USER MANUAL ETU02-MUX 2/4 Port G.703 E1 Multiplexer with SNMP

Transcription

1 USER MANUAL ETU02-MUX 2/4 Port G.703 E1 Multiplexer with SNMP CTC Union Technologies Co.,

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3 LEGAL The information in this publication has been carefully checked and is believed to be entirely accurate at the time of publication. CTC Union Technologies assumes no responsibility, however, for possible errors or omissions, or for any consequences resulting from the use of the information contained herein. CTC Union Technologies reserves the right to make changes in its products or product specifications with the intent to improve function or design at any time and without notice and is not required to update this documentation to reflect such changes. CTC Union Technologies makes no warranty, representation, or guarantee regarding the suitability of its products for any particular purpose, nor does CTC Union assume any liability arising out of the application or use of any product and specifically disclaims any and all liability, including without limitation any consequential or incidental damages. CTC Union products are not designed, intended, or authorized for use in systems or applications intended to support or sustain life, or for any other application in which the failure of the product could create a situation where personal injury or death may occur. Should the Buyer purchase or use a CTC Union product for any such unintended or unauthorized application, the Buyer shall indemnify and hold CTC Union Technologies and its officers, employees, subsidiaries, affiliates, and distributors harmless against all claims, costs, damages, expenses, and reasonable attorney fees arising out of, either directly or indirectly, any claim of personal injury or death that may be associated with such unintended or unauthorized use, even if such claim alleges that CTC Union Technologies was negligent regarding the design or manufacture of said product. TRADEMARKS Microsoft is a registered trademark of Microsoft Corp. HyperTerminal is a registered trademark of Hilgraeve Inc. FCC WARNING: This equipment has been tested and found to comply with the limits for a Class A digital device, pursuant to Part 15 of the FCC Rules. These limits are designed to provide reasonable protection against harmful interference when the equipment is operated in a commercial environment. This equipment generates, uses, and can radiate radio frequency energy and if not installed and used in accordance with the instruction manual may cause harmful interference in which case the user will be required to correct the interference at their own expense. NOTICES: (1) The changes or modifications not expressively approved by the party responsible for compliance could void the user's authority to operate the equipment. (2) Shielded interface cables and AC power cord, if any, must be used in order to comply with the emission limits. (3) This is a Class A product. In a domestic environment this product may cause radio interference in which case the user may be required to take adequate measures. CISPR PUB.22 Class A COMPLIANCE: This device complies with EMC directive of the European Community and meets or exceeds the following technical standard. EN Limits and Methods of Measurement of Radio Interference Characteristics of Information Technology Equipment. This device complies with CISPR Class A. CE NOTICE Marking by the symbol CE indicates compliance of this equipment to the EMC directive of the European Community. Such marking is indicative that this equipment meets or exceeds the following technical standards: EN 55022:1994/A1:1995/A2:1997 Class A and EN :1995, EN :1995 and EN :1997

4 CTC Union Technologies Co., Ltd. Vienna Technology Center 8F, No. 60, Zhouzi St., Neihu District, Taipei, 114 Taiwan ETU02-MUX 4 Port MUX, Fractional E1, Installation and Operation Manual Version 3.0 May 2008 This manual supports the following models: ETU02-MUX.2-XX-AC, 2 Port MUX, universal AC ETU02-MUX.2-XX-DC, 2 Port MUX, DC model ETU02-MUX.2-XX-DP, 2 Port MUX, Dual Power AC+DC model ETU02-MUX.4-XX-AC, 4 Port MUX, universal AC ETU02-MUX.4-XX-DC, 4 Port MUX, DC model ETU02-MUX.4-XX-DP, 4 Port MUX, Dual Power AC+DC model Firmware Version notice: V1.16 Last version of old ETU02-MUX, 2 or 4 port operation V1.20 Main and Sub reversed, no Sub E1 support, 2 or 4 port (interim version) V1.21 New Version, 4 port, supports optional Sub E1 V1.22 New Version, 2 port, supports optional Sub E1 V1.37 Version as of printing, 2 ports, supports SNMP option and added loop back features V1.38 Version as of printing, 4 ports, supports SNMP option and added loop back features V1.39 Corrected Test LED to light during V.54 Loopback V1.40 fixed a bug in Timeslot mapping in SNMP V1.41 Make Sub E1 SI bit follow Main E1 SI bit V1.42 Add 4 digit password protection to LCD

5 Table of Contents Chapter 1. Introduction Introduction Functional Description Typical System Applications E1 signal structure ETU02-MUX Capabilities TECHNICAL SPECIFICATIONS...13 Chapter 2. Installation General Site Preparation Mechanical Assembly Electrical Installation Power connection Rear panel connectors DIP Switch Setting and DATA Interface Module Replacement Caution Procedure...19 Chapter 3. Front Panel Operation General Controls and Indicators Menu Operation Top Level Menus System Parameter Detail Main Link Parameter Detail Sub Link Parameter Detail Timeslot Mapping Detail Data Port Parameter Detail Control Port Parameter Detail Loop back Parameter Detail BERT Test Detail Date & Time Display & Set Detail Miscellaneous Setup Detail Alarm Buffer Display Detail Performance Monitor Display Detail...32 Chapter 4. Console Port Operation General Terminal Connection Menu System Detail...34 i

6 Table of Contents Chapter 5. Test and Diagnostics General Status Indicators and Messages User activated loop back Chapter 6. SNMP Operation Introduction Required tools and supplies Installation Procedure (Please refer to the attached drawing) SNMP Overview Configuring the ETU02-MUX SNMP Agent MIB detail for ETU02-MUX ETU02-MUX Trap Codes Chapter 7. Troubleshooting Instructions Appendix A. DIP Switch Setting A-1 DSW1 Setting A-2 DSW2 Main E1 Line Impedance Setting A-3 SW1 Sub E1 Line Impedance Setting A-4 Jumper CHASS1 Frame Ground Setting Appendix B. Connections B-1. E1 Line Connectors B-1.1 D-15 connector B-1.2 BNC connector B-2. RS-232/Alarm Port Connector C-1. X.21 Data Channel Module C-2. V.35 Data Channel Module C-3. RS-530 Data Channel Module C-4. RS-232 Data Channel Module C-5. RS-530 to RS-449 Adapter Cable C-6. G K Co-directional Interface Module C-7. NRZ/BNC 64K ~ 2048Kbps NRZ Interface Module C-8. ET10/100 Ethernet Bridge Module C-9. ET100R Ethernet Router Module Appendix D. Menu System ii

7 Chapter 1. Introduction 1-1. Introduction Chapter 1. Introduction The ETU02-MUX provides an economical multiplexing solution for E1 and Fractional E1 network services. Up to two (or four depending upon model) DTE devices may be linked to an ETU02-MUX at combined data rates of 56Kbps to 1984Kbps. The ETU02-MUX also provides one optional E1 sub-link, which may be connected over a public E1 network. The E1 sub-link will perform Drop & Insert with user-defined timeslot connections from a PABX or other E1 equipment to E1 network services. The ETU02-MUX supports local control and diagnostics via the LCD display, keypad and LED status indicators located on the front panel or via the console port connection. The optional SNMP port provides SNMP Simple Network Management Protocol System functions, which allow the user to remotely control and diagnose the system. These features enable users to easily configure the unit, execute the in-service diagnostics and monitor the network status either locally or remotely Functional Description The ETU02-MUX data channels support user-selectable transmission rates, which are integer multiples of 56 or 64kbps, up to a maximum 1.984Mbps (31 timeslots), for a line attenuation of up to -43 db on twisted pair or coax cable. An integral LTU is built-in, providing an approximate operating range of up to 2km (using 22AWG). The ETU02-MUX packs the data channels into E1 link time slots in user-selected time slots, the unused time slots may insert IDLE code or any user selectable code. As of the writing of this manual, the ETU02-MUX has nine types of user-replaceable data channel modules, which include: RS-232, V.35, X.21, RS-530, RS-449, G k Codirectional, NRZ, 10/100Base-TX Bridge and 10/100Base-TX Router. The ETU02-MUX fully meets all of the E1 specifications including ITU G.703, G.704, G.706, G.732, and G.823. The ETU02-MUX features V.54 diagnostic capabilities for performing remote digital loop back. The operator at either end of the line may test both the ETU02 MUX and the E1 line in the digital loop back mode. The loop back is controlled by either menu selection on the local LCD, local terminal, SMNP or by the DTE interface for V.35, RS-232 and RS-530. Other, non-standard loop back options are also available via LCD, local terminal or SNMP control. 7

8 Chapter 1. Introduction During loop back testing an internal pseudo random test pattern is generated, according to ITU-T, for direct end-to-end integrity testing. The Error indicator flashes for each bit error detected. Multiple clock source selection provides maximum flexibility in connecting both the E1 and user interfaces. The ETU02-MUX has the flexibility to meet the timing requirements of various system configurations. The timing mode for the E1 link and for the user channel are selected by the setting of configuration data via the front panel LCD display, terminal mode console port, or via option SNMP management connection. The E1 link may be clocked from the E1 recovered receive clock (main E1 link or sub E1 link), from any one of the user data ports, or from the internal oscillator. The ETU02-MUX AC model operates from 90VAC ~ 250VAC while the DC model operates from 18 to 72VDC. The DP or Dual Power model provides connection to both AC and DC power sources. The unit is built in a single unit EIA compliant 19 rack mountable case that may also be placed on desktops or shelves. 8

9 Chapter 1. Introduction 1-3. Typical System Applications General In a typical application (Figure 1-1), the ETU02-MUX is used to connect the synchronous data channels of two routers and the local and remote LANs over an E1 line. Figure 1-1: Example 1; Two Channel Typical Application Figure 1-2: Example 2; Four Channel plus E1 Sub-Link Application Figure 1-3: Example 3; Cascade ETU02 from E1 Sub-Link Application The fractional E1 data service is based on the assumption that the combined user data rate of all channel modules plus Sub-Link is equal to or is a fraction of the full available E1 bandwidth, in multiples of 56K or 64K. Up to four data channels may be connected plus an optional E1 sub-link. 9

10 Chapter 1. Introduction 1-4. E1 signal structure The E1 line operates at a nominal rate of 2.048Mbps. The data transferred over the E1 line is organized into frames, with each E1 frame containing 256 bits. The 256 bits are organized as 32 time slots of eight bits each and carry the data payload. E1 transmissions utilize two main types of framing: Frame Alignment Signal (FAS) and Multi-Frame Alignment Signal (MFAS). Framing is necessary in order for equipment receiving the E1 signal to be able to identify and extract the individual channels. PCM-30 (CAS) transmission systems use MFAS framing along with FAS framing. PCM-31 (CCS) transmission systems use only FAS framing. Frame Alignment Signal (FAS) The Mbps frame consists of 32 individual time slots (numbered 0-31). As described previously, each time slot consists of an individual 64 Kbps channel of data. In the FAS format, time slot 0 of every other frame is reserved for the frame alignment signal pattern. Alternate frames contain the FAS Distant Alarm indication bit and others bits reserved for national and international use. Multi-Frame Alignment Signal (MFAS) MFAS framing uses Channel Associated Signaling (CAS) to transmit the A/B/C/D bits signaling information for each of 30 channels. This method uses the 32 time slot frame format with time slot 0 dedicated for the Frame Alignment Signal (FAS) and time slot 16 dedicated for the Multi-Frame Alignment Signal (MFAS) and the Channel Associated Signaling (CAS). E1 line signal The basic E1 line signal is coded using the Alternate Mark Inversion (AMI) or HDB3 rule. In the AMI format, ones are alternately transmitted as positive and negative pulse, whereas zeros are transmitted as a zero voltage level. AMI is not used in most Mbps transmissions because synchronization loss occurs during long strings of data zeros. In the HDB3 format, a string of four consecutive zeros is replaced with a substitute string of pulses containing an intentional bipolar violation. The HDB3 code substitutions provide high pulse density so that the receiving equipment is able to maintain synchronization with the received signal. 10

11 Chapter 1. Introduction 1-5. ETU02-MUX Capabilities E1 link line coding The ETU02-MUX supports two E1 line codes: AMI coding. HDB3 coding. E1 framing formats The ETU02-MUX supports three formats: Unframed format. (in Unframed, only Data port 1 is supported) FAS (CCS, PCM-31) format. (TS0 reserved) MFAS (CAS, PCM-30) format. (TS0 and TS16 reserved) User data channel rates The ETU02-MUX supports user data channel rates which are a multiple of 56 or 64kbps. For maximum flexibility, the ETU02-MUX supports combined data rates up to 1.984Mbps. The ETU02-MUX supports flexible time slot assignment, allowing the user to freely specify the selection of time slots, in sequence or randomly, for each data channel. User data channel interface The ETU02-MUX has nine types of user data channel modules: RS-232, V.35, X.21, RS- 530, G K Co-directional, NRZ, 10Base-T Bridge, 10/100Base-TX Bridge and 10/100Base-TX Router. The ETU02-MUX also supports RS-449 data channel via an interface adapter cable attached to the RS-530 channel module. The desired interface is achieved by installing the appropriate type of channel module in the ETU02-MUX. The ETU02-MUX/2 supports two data channel modules, while the ETU02-MUX/4 supports up to four channel modules System Timing Considerations The ETU02-MUX has the flexibility to meet the timing requirements of various system configurations. The timing mode for the E1 link and for the user channel are selected by the setting of configuration data via the front panel LCD display, terminal mode console port, or via option SNMP management port connection. 11

12 Chapter 1. Introduction E1 link timing The ETU02-MUX E1 link receive path always operates on the receive clock. The ETU02-MUX recovers the receive clock from the received E1 link data signal. The source of the ETU02-MUX E1 link transmit clock can be selected by the user. The following E1 link transmit timing modes are available. Loop back timing: The ETU02-MUX E1 link transmit clock is locked to the recovered receive clock (Main link E1 or Sub link E1). This is usually the timing mode selected for network operation. Internal timing: The ETU02-MUX E1 link transmit clock is derived from the internal clock oscillator. This timing mode is necessary in point-to-point applications over leased line. In this case, one ETU02-MUX must use the internal oscillator, and the others must operate from the recovered clock. External timing: The ETU02-MUX E1 link transmit clock is locked to the clock signal provided by the user DCE connected to one of the user s data channels. When the data channel is used as the clock source, the data channel must use clock timing mode 2 (DTE1) or 4 (DTE3). User data channel timing The ETU02-MUX has four user data channel clocking modes: Clock mode 1 (DCE): The ETU02-MUX data channel operates as a DCE and provides the transmit and receive clocks (recovered timing) to the data terminal equipment connected to the user channel. The clocks are locked to the master timing. Clock mode 2 (DTE 1): The ETU02-MUX data channel operates as a DTE (crossover cable required) and supplies the receive clock to the synchronous DCE, and accepts a transmit clock from the DCE (from the ETC pin). The DCE must transmit data at the rate of the clock signal supplied by the ETU02-MUX. This timing mode is also referred to as "transparent timing". Clock mode 3 (DTE 2): The ETU02-MUX data channel operates as a DTE (crossover cable required) and accepts both transmit clock (from the ETC pin) and receive clock (from the ERC pin) from the user DCE equipment. NOTE: The X.21 data channel cannot be operated in clock timing mode 3 (DTE2). Clock mode 4 (DTE 3): The ETU02-MUX data channel operates as a DTE (crossover cable required) and accepts both transmit clock and receive clock (both from the ETC pin) from the user DCE equipment. 12

13 Chapter 1. Introduction 1-6. TECHNICAL SPECIFICATIONS Main link E1 and sub link E1 Framing -Unframed/Framed (sub link framed only) -CCS (PCM31)/CAS (PCM30) -CRC4 ON/OFF Bit Rate Mbps Line Code -AMI -HDB3 Line Impedance -Unbalanced 75 ohms -Balanced 120 ohms Relative Receive Level 0 to -43dB Pulse Amplitude -Nominal 2.37V±10% for 75 ohms -Nominal 3.00V±10% for 120 ohms Zero Amplitude ±0.1V Transmit Frequency Tracking Internal Timing ±30 ppm Loop back Timing ±50 ppm External Timing ±100 ppm Jitter Performance According to ITU-T G.823 Complies With ITU-T G.703, G.704, G.706 and G.732 Interface Connectors -15-pin, D-type Female (AT&T pub 62411) (BD15 to USOC RJ48C adapter included) -BNC 13

14 Chapter 1. Introduction User Data Channels Interface Types Interface Connectors V.35 Interface X.21 Interface RS-232 Interface RS-530 Interface RS-449 Interface G.704/64K I/F NRZ Interface 10Base-T Ethernet 10/100Base-T Ethernet Line Code Data Rate Clock Modes Clock Mode 1 (DCE) Clock Mode 2 (DTE1) Clock Mode 3 (DTE2) Clock Mode 4 (DTE3) Control Signals Time slot allocation -V.35 -X.21 -RS-232 -RS-530/V.36 -RS-449 (via adapter cable) -G.703/64K Co-directional -NRZ -10/100Base-TX Bridge (ET100) -10/100Base-TX Router (ET100R) 34 pin, Female 15 pin, D-type Female 25 pin, D-type Female 25 pin, D-type Female 37 pin, D-type Male(via adapter cable) 15 pin, D-type Female 4, BNC Female RJ-45 Shielded RJ-45 Shielded NRZ (except G.603/64K and Ethernet) n 56kbps or n 64kbps where n equal 1 to 31 in CCS and n equal 1 to 30 in CAS Receive and transmit clock (recovered) to the synchronous DTE Receive clock to the synchronous, and transmit clock from the synchronous DCE device Receive and transmit clock from the synchronous DCE (from ETC and ERC pin ) Receive and transmit clock from the synchronous DCE (all form ETC pin). -CTS constantly ON or follows RTS -DSR constantly ON, except during test loops -DCD constantly ON, except during signal loss User defined, randomly assignable Setup/Configuration LCD Pushbutton Switches Password Protection 2 rows of 16 characters -Menu/ESC -Left Arrow -Right Arrow -Enter user settable 4 character password 14

15 Chapter 1. Introduction LED indicators PWR Green Power Signal Loss Red E1 link signal loss Sync Loss Red E1 link sync loss Alarm Red E1 link alarm, includes: BPV error / CRC4 error / Frame slip / All ones (AIS) / Remote alarm Signal Loss Red Sub-E1 link signal loss Sync Loss Red Sub-E1 link sync loss Alarm Red Sub-E1 link alarm, includes: BPV error / CRC4 error / Frame slip / All ones(ais) / Remote alarm CH1~CH4 Yellow RD/TD activity indicators for Data Channels Test Error Red Bit errors Test Red Unit in Loop back or pattern test Diagnostic tests Test loops -Main link local analog loop back -Main link local digital loop back -Main link local payload loop back -Main link remote analog loop back -Main link remote payload loop back -Sub link local analog loop back -Sub link local digital loop back -Sub link remote loop back -Data channel (1-4) local analog loop back -Data channel (1-4) local digital loop back -Data channel (1-4) V.54 loop back BERT test pattern ^ ^20-1 -QRSS -2^23-1 -All ones -All zeros -ALT -Double ALT ( ) -3 in 24-1 in 16-1 in 8-1 in 4 15

16 Chapter 1. Introduction RS-232/Alarm port Port interface Port connector Data rate (*default) Data format Alarm relay V.24/RS-232 asynchronous, DCE 9 pin D-type female 300, 1200, 2400, 4800, 9600*, and bps -One start bit -8 data bits -No parity -One stop bits -Floating pair of NO and NC contacts -Contact ratings: 1A at 30 VDC resistive or 0.5A at 125 VAC resistive Physical Height: 45 mm (1.75") Width: 438 mm (17.25") Depth: 233 mm (9.17") Weight: 3.5 kg Power supply Voltage (AC model) Voltage (DC model) Voltages (DP model) Frequency Power consumption 90 ~ 250 VAC 18 ~ 72 VDC 90 ~ 250 VAC + 18 ~ 72 VDC 47 to 63 Hz for AC power 15 Watts Environment Temperature Humidity 0-50 C / F 0 to 90% non-condensing 16

17 Chapter 2. Installation 2-1. General Chapter 2. Installation This chapter provides detailed instructions for mechanical installation of the ETU02 MUX. Following the completion of installation, please refer to Chapter 3 for front panel operating information and Chapter 4 for console port operating information Site Preparation Install the ETU02 MUX within reach of an easily accessible grounded AC outlet. The outlet should be capable of furnishing 90 to 250 VAC. Allow at least 10cm (4 inch) clearance at the rear of the ETU02 MUX for signal lines and interface cables Mechanical Assembly The ETU02 MUX is designed for tabletop, shelf or rack mount installation, and except for rack mount installation, is delivered completely assembled. Rack mounted applications require installation of additional rack mounting ears. No provisions are made for bolting the ETU02 MUX to the tabletop Electrical Installation Power connection AC power is supplied to the ETU02 MUX through a standard IEC 3-prong plug. (Refer to Figure 2-1) The ETU02 MUX should always be grounded through the protective earth lead of the power cable Rear panel connectors The data channel module interfaces install into the rear panel from inside the ETU02 MUX (Refer to Figure 2-1) and consist of a DB15pin connector for X.21 and G K, DB25pin connector for RS-530 and RS-232, 34-pin M34 connector for V.35, and 8 pin RJ-45 connectors for the Ethernet interfaces. The E1 line and E1 sub-link connectors incorporate a pair of DB15pin each and two pairs of BNC Coax connectors. (Appendix C provides detailed information for the various interface modules). AC Input DC Input Figure 2-1 ETU02 MUX rear panel 17

18 Chapter 2. Installation E1 Line side DB-15 Connector The pin assignment for DB-15 connector follows AT&T Pub as follows: Pin: Function: 1 TTIP (Transmit data out) 9 TRING (Transmit data out) 3 RTIP (Receive data in) 11 RRING (Receive data in) BNC coax connector Two BNC coax connectors marked RX and TX (Same function as the E1 line DB15 connector), provide unbalanced 75 Ohm connections for the E1 line. DB15 to RJ-45 adapter, RJ-45 connector When E1 connection requires RJ-45 physical connection, the DB15 to RJ-45 adapter provides the standard USOC RJ-48C pin assignment for the E1 connections. (Pin 1 = RRING, Pin 2 = RTIP, Pin 4 = TRING, & Pin 5 = TTIP) Cable and Termination Use a shielded twisted pair cable between the ETU02-MUX and the DTE device. The receivers on the ETU02-MUX are 100 Ohm terminated (For X.21 and RS-530). If problems are encountered with the connection to the DTE interface, make sure that the DTE interface is terminated correctly. 18

19 Chapter 2. Installation 2-5. DIP Switch Setting and DATA Interface Module Replacement Caution To avoid accidental electric shock, disconnect the ETU02-MUX power cord before opening the cover. Access inside the equipment is permitted to authorized and qualified service personnel only Procedure a. Turn power OFF. Disconnect the power cord from the AC outlet. b. Loosen the captive thumb screws on the left and right sides of the rear panel. c. Slide the outer housing forward or slide the main PCB assembly back to reveal the main PCB and data modules. d. Adjust the DIP switches as required, according to table 2-1. (Appendix A describes the DIP switch functions). e. With the exception of the V.35 module, remove the two flat-head screws on the exterior (rear panel) portion of the Channel Module. f. Channel module PCB assemblies are secured with three Philips Head machine screws. The main PC board designations CN9, CN8, CN7 and CN6 correspond to Data Port modules 1, 2, 3 and 4 respectively. Remove the screws and carefully lift the module off the internal 32 pin connector. Install a module with the reverse procedure, taking care to properly align the pins, seat the board, and apply the three screws. Visually check that all pins are seated and that none are bent. g. Slide the main PCB assembly back into the outer housing and tighten the thumb screws. Item Function Possible Table 2-1 Switch Factory Settings Designation Setting 1 Reserved On / Off DSW1-1 Off 2 Reserved On / Off DSW1-2 Off 3 Reserved On / Off DSW1-3 Off 4 Reserved On / Off DSW1-4 Off 5 Reserved On / Off DSW1-5 Off 7 Main E1 Impedance All On=75Ω, All Off=120Ω DSW2-1~5 All Off 8 Sub E1 Impedance All On=75Ω, All Off=120Ω SW1-1~5* All Off 9 Frame ground DIS: Not connected to signal ground CHASS1 DIS CON: Connected to signal ground DSW1 and DSW2 are located on the main PC Board. *Switch SW1 is located on the Sub E1 Interface card. 19

20 Chapter 2. Installation Chassis GND Jumper Set this jumper to "CON" to connect logic ground to chassis. Set to "DIS" to separate logic and chassis grounds. Please refer to the following figure for location of DIP switch and chassis jumper. Sub E1 Card DIP Switches Ground Jumper Interface Modules SNMP Slot (option) Figure 2-2 : ETU02-MUX Main PCB Assembly Figure 2-3. Interface Module Insertion/removal 20

21 Chapter 3. Front Panel Operation 3-1. General Chapter 3. Front Panel Operation This chapter describes the ETU02-MUX controls and indicators, and explains operation setup procedures using the front panel LCD and menu keys. Installation procedures (in Chapter 2) must be completed and checked before attempting to operate the ETU02-MUX Controls and Indicators All controls (push-button switches), LCD display and LED indicators are located on the ETU02-MUX front panel. The momentary on pushbutton switches are used to activate menu selections and select parameter settings. Figure 3-1 ETU02-MUX Front Panel Use the < and > function keys to browse the menus and select parameters. Use the Menu/ESC function key to return to a previous menu or to abandon setup. Use the Enter function key to set a parameter of a selection or to enter a sub-menu. 21

22 Chapter 3. Front Panel Operation 3-3 Menu Operation Top Level Menus The following are the 12 top level Menus. Press an arrow key to select another top level Menu or press ENTER to reach a sub menu. < A D M I N I S T R A T I O N > L O G I N P W D : 0 _ If a login password is set, this will be the first greeting screen. (Factory default has no password.) If a password is not set, the following will be the greeting screen. < S Y S T E M > P A R A M E T E R Set the Master and Fallback timing. < M A I N L I N K > P A R A M E T E R Set the Frame type, CRC mode, idle code, Line code and RAI for main E1 link. < S U B L I N K > P A R A M E T E R Set the Frame type, CRC mode, idle code, Line code and RAI for E1 sub-link. < T I M E S L O T > M A P P I N G Assign the E1 timeslots to the Data Channels and/or E1 sub-link. < D A T A P O R T > P A R A M E T E R Data Port Informational screen and settings for Clock Mode, Handshaking, and multiplier (n56k or n64k). < C O N T R O L P O R T > P A R A M E T E R Setup for the terminal console port. Default is 9600, 8bit, no parity. Only the baud rate is selectable. 22

23 Chapter 3. Front Panel Operation < L O O P B A C K > P A R A M E T E R Enable main link, sub-link, or data channel Loop back. < B E R T T E S T > P A R A M E T E R Enable BERT, select channel, select pattern, and do error insertion. < D A T E & T I M E > D I S P L A Y & S E T Display and set the internal real time clock of the ETU02-MUX. < M I S C E L L A N E O U S > S E T U P Set the mode of the LCD backlight either Off, On, or Auto. < A L A R M B U F F E R > D I S P L A Y Display the Alarm Buffer. < P E R F O R M A N C E > D I S P L A Y Display the performance registers. 23

24 Chapter 3. Front Panel Operation System Parameter Detail The following screens show the setup screens under the System Parameter Main Screen. < S Y S T E M > P A R A M E T E R Press ENTER, MASTER TIMING sub-menu will be displayed. Master Timing sets the source for the timing in the ETU02-MUX. < M A S T E R T I M I N G > M A I N L I N K Pressing ENTER again will place the cursors on the parameter selection line. The arrow keys are now used to browse the available parameters. Available parameters under Master Timing are: MAIN LINK; Timing is recovered from the main E1 link. SUB LINK; Timing is recovered from the E1 sub-link. INT OSC; Timing is provided by the internal oscillator of the ETU02-MUX. CH 1 LINK; Timing is recovered from the Data Channel 1. CH 2 LINK; Timing is recovered from the Data Channel 2. CH 3 LINK; Timing is recovered from the Data Channel 3. CH 4 LINK; Timing is recovered from the Data Channel 4. Press the ENTER key on the selected parameter. The cursors will return to the top line. Use the RIGHT arrow key to select the next sub-menu (BACKUP TIMING). The settings of backup timing are used as a "fallback" in case the main timing sync is lost. A typical setting for the backup timing would be the choice of internal oscillator. < B A C K U P T I M I N G > I N T O S C Pressing ENTER will place the cursors on the parameter selection line. The arrow keys may now be used to browse the available parameters. Available parameters under Backup Timing are: MAIN LINK; Timing is recovered from the main E1 link. SUB LINK; Timing is recovered from the E1 sub-link. INT OSC; Timing is provided by the internal oscillator of the ETU02-MUX. 24

25 Chapter 3. Front Panel Operation Main Link Parameter Detail The following screens show the setup screens under the Main Link Parameter Screen. < M A I N L I N K > P A R A M E T E R Press ENTER and the MAIN LINK sub-menu will be displayed. Main Link sets the frame type, CRC mode, idle code, Line Code and RAI state for the main E1 link of the ETU02-MUX. < M A I N L I N K > F R A M E : C C S Use the arrow keys to browse the individual link parameters (frame, CRC, etc.). Press ENTER on the parameter to select it with the cursors. Now use the arrow keys to browse the available settings for that parameter. The following is a breakdown of parameters and available settings: FRAME; CCS, CAS, or UNFRAME, CCS default. CRC-4; OFF or ON, OFF default. IDLE CODE; any hex code from 00 to FF, 7E default. RAI; (Remote Alarm Indicator) DISABLE or ENABLE, DISABLE default. LINE CODE; HDB3 or AMI, HDB3 default. IMPEDANCE; will display current setting depending upon the internal DIP switch settings. RMT LOOP; OFF or ON, OFF default. Will place remote unit into loop back. For transmission of unframed data, select UNFRAME for the main E1 link. In this case, all the Data Ports except CH1 are disabled (the data rate of CH1 is automatically set to Mbps) Sub Link Parameter Detail The following screens show the setup screens under the Sub Link Parameter Screen. < S U B L I N K > P A R A M E T E R Press ENTER and the SUB LINK sub-menu will be displayed. Sub Link sets the frame type, CRC mode, idle code, Line Code and RAI state for the E1 sub-link of the ETU02-MUX. < S U B L I N K > F R A M E : C C S The parameters and settings for the E1 sub-link are the same as for the Main Link above. 25

26 Chapter 3. Front Panel Operation Timeslot Mapping Detail The following screen is an example of Timeslot Mapping. < T I M E S L O T > M A P P I N G Press ENTER. F The E1 frame is shown with 32 timeslots, top row left to right are TS0-15, while the bottom row displays the settings for TS Press ENTER to move to the next TS, use the arrow keys to assign the timeslot as follows: F = Framing (CCS/CAS) always on TS 00 S = Signaling (CAS) always on TS 16 N = not assigned 1 = Data Channel 1 2 = Data Channel 2 3 = Data Channel 3 4 = Data Channel 4 D = Data on E1 sub-link V = Voice on E1 sub-link TS 00:Cannot be assigned in CCS or CAS mode of MAIN LINK to anything but Framing. TS 16:Cannot be assigned in CAS mode of MAIN LINK to anything but Signaling Data Port Parameter Detail The following shows the setup screens under the Data Port Parameter Screen. < D A T A P O R T > P A R A M E T E R Press ENTER < C H 1 : V. 3 5 D C E > N K b p s Use the arrow keys to display information for the other Data Port channels. The first line shows the port number followed by the interface type and clock mode. The second line shows that channel s multiplier value (56k or 64k) and the bandwidth used by the channel. In the above display, channel 1 is using a V.35 interface, clock mode set to DCE, 64k multiplier and 448kbps bandwidth. 26

27 Chapter 3. Front Panel Operation While in the Data Port display, only the clock mode, handshaking, multiplier and clock polarity values are user settable. The interface type is auto-detected and the data bandwidth is calculated by multiplying the multiplier value times the number of timeslots assigned to the channel under the Timeslot Mapping screen. Pressing ENTER again will bring up the individual Data Port channel display. < C H A N N E L 1 > M U L T I P L I E R : N 6 4 Use the arrow keys to browse the available settings under the Data Port channel. They are: Multiplier value; N64 or N56, default is N64 Clock mode; DCE, DTE1, DTE2, DTE3, default is DCE CTS; ON or RTS, default is ON TC OUT; NORMAL or INVERT, sets the polarity of the Transmit Clock RC OUT; NORMAL or INVERT, sets the polarity of the Receive Clock Press the ENTER key to move the cursors to the Multiplier field. Select either N64 or N56 using the arrow keys, then press ENTER. Press the right arrow key to select the Clock Mode screen. < C H A N N E L 1 > C L K M O D E : D C E Press ENTER and use the arrow keys to browse the settings for CLK MODE. Press ENTER when the desired mode is shown. Use the arrow key to move on to the last parameter setting for CTS. < C H A N N E L 1 > C T S : O N Press ENTER to move the cursors to the CTS field. Select either ON or RTS using the arrow keys, then press ENTER. Press the MENU/ESC key to back out of the Channel 1 settings. Use the arrow key to select the other Channels and follow the same procedure to set multiplier, clock mode, handshaking and clock polarity settings. If the Data Port channel module in not installed a display similar to the following will be displayed. < C H 3 : N C D C E > N 6 4 N C 27

28 Chapter 3. Front Panel Operation Control Port Parameter Detail The following shows the setup screens under the Control Port Parameter Screen. < C O N T R O L P O R T > P A R A M E T E R Press ENTER C O N T R O L P O R T b p s 8 N O N E This screen shows the default settings for the Control Port. Only the speed parameter is settable for the Control Port. Speed; 300, 600, 1200, 2400, 4800, 9600, and 19200, default is Data Length; fixed at 8 bits only. Parity; fixed at NONE only. Follow the normal screen procedures to set the speed parameter, then press MENU/ESC to return to the top menu Loop back Parameter Detail The following show the setup screens under the Loop back Parameter Screen. < L O O P B A C K > P A R A M E T E R Press ENTER < M A I N L I N K > L O O P B A C K O F F Use the arrow keys to browse the available options for loop back setting. By default, all loop backs are off. The details are as follows: Main Link; Loop back Off, Local Analog, Local Digital, Local Payload, Remote Analog, or Remote Payload Sub Link; Loop back Off, Local Analog, Local Digital, or Remote Loop Channel 1; Loop back Off, Local Analog, Local Digital, or V.54 Loop Channel 2; Loop back Off, Local Analog, Local Digital, or V.54 Loop Channel 3; Loop back Off, Local Analog, Local Digital, or V.54 Loop Channel 4; Loop back Off, Local Analog, Local Digital, or V.54 Loop All Channels; use this option to quickly turn loop back Off for all channels. 28

29 Chapter 3. Front Panel Operation BERT Test Detail The following show the setup screens under the BERT test Parameter Screen. < B E R T T E S T > P A R A M E T E R Press ENTER < B E R T T E S T > F U N C T I O N : O F F Use the arrow keys to browse the available options for BERT test setting. The details are as follows: Function; Off or On, default Off. Use to start BERT. Channel; Ch1, Ch2, Ch3, Ch4, SL-ML (sub-link/main-link), or SL-SL, default is Ch1 Pattern; 511, 2047, 2e15-1, 2e20-1, QRSS, 2e23-1, All 1, All 0, Alt, 0011, 3in24, 1in16, 1in8, or 1in4, default is 511 Err Ins; NONE, Single,10e-1, 10e-2, 10e-3, 10e-4, 10e-5, 10e-6, or 10e-7, default is NONE Result; display the received bit errors and error rate. BERT TEST ERROR INSERT (SINGLE) B E R T T E S T < E R R I N S : S I N G L E > When selecting the Single Error insert the following screen will display. B E R T S I N G L E E R R. I N S E R T [ E N T E R ] Press ENTER each time you want to insert an error. 29

30 Chapter 3. Front Panel Operation Date & Time Display & Set Detail The following shows the setup screens under the Date & Time Parameter Screen. < D A T E & T I M E > D I S P L A Y & S E T Press ENTER to display current Date and Time. D A T E / 0 3 / 0 1 T I M E 0 0 : 0 0 : 0 8 Press ENTER again to define date and time. The cursor will be in the year field. Use the arrow keys to increment or decrement the year. Press ENTER to save and move on to the month field. Use the arrow keys again to change the month, press ENTER to save and move to the Day field. Continue this procedure for the time settings and then press MENU/ESC to start the clock from the set time. The clock used in the ETU02-MUX is fully Y2K compliant. D A T E / 0 6 / 2 7 T I M E 1 4 : 1 3 : Miscellaneous Setup Detail The following shows the setup screens under the Miscellaneous Parameter Screen. < M I S C E L L A N E O U S > S E T U P Press ENTER. < M I S C E L L A N E O U S > L C D L I G H T : A U T O Use the arrow keys to browse the available options for the LCD back lighting. They are: AUTO; The backlight will automatically turn off in 5 minutes if no key is pressed. The backlight will automatically turn on again if any key is pressed. Default is AUTO. ON; The backlight will remain permanently on. OFF; The backlight will remain permanently off. Follow the normal menu procedures. From the Miscellaneous Setup menu use the arrow keys to browse to the RESET TO DEFAULT parameter function. 30

31 Chapter 3. Front Panel Operation < M I S C E L L A N E O U S > R E S E T T O D E F A U L T Press ENTER. R E S E T T O D E F A U L T P R E S S [ E N T E R ] Press the ENTER key to completely reset all parameters to their original factory defaults. Follow the normal menu procedures. From the Miscellaneous Setup menu use the arrow keys to browse to the Modify PWD (password) function. (This feature added in f/w version 1.42.) Any password value entered from 0001 to 9999 is valid will disable the password. < M I S C E L L A N E O U S > M O D I F Y P W D Press Enter. < M o d i f y P W D > I N P U T P W D : 0 _ Use right arrow to increase, left arrow to decrease value, 0~9 M o d i f y P W D < I N P U T P W D : 3 _ > Press Enter. Use right arrow to increase, left arrow to decrease value, 0~9. M o d i f y P W D < I N P U T P W D : 3 0 > Continue until four digits are entered. Then repeat again for the password check. < M o d i f y P W D > C h e c k P W D : 0 _ If the two entered passwords match, it will be accepted. < M o d i f y P W D > P a s s w o r d C o r r e c t To clear the password, enter the value 0000 twice. < M o d i f y P W D > P a s s w o r d D I S A B L E 31

32 Chapter 3. Front Panel Operation Alarm Buffer Display Detail Use this function to display and/or clear the Alarm Buffer. < A L A R M B U F F E R > D I S P L A Y Use the arrow keys to select between DISPLAY and CLEAR. To display press ENTER. < D I S P L A Y A L A R M > B U F F E R Press ENTER to display buffer. Refer to Table 5-2 in Chapter 5 TEST and DIAGNOSTICS, for the meaning of the displayed alarms. If you use the arrow keys to browse to the CLEAR function, the following will be displayed. < C L E A R A L A R M > B U F F E R [ E N T E R ] Press ENTER to clear the alarm buffer or press Menu/ESC to exit Performance Monitor Display Detail Use this function to display and/or clear the Performance Data. < P E R F O R M A N C E > D I S P L A Y The Performance Display is used to show the CRC-4 (checksum) count (CRC4 Cnt) or Bipolar Violations (BPV) count, Current Error Seconds (CURR ES), Current Unavailable Seconds (CURR UAS), Long Term Errored Seconds (LONG ES), Long Term Unavailable Seconds (LONG UAS), Current Seconds (CURR SEC) and Long Seconds (LONG SEC). Refer to Appendix B, for the detailed meaning of the performance displays. Press ENTER. Press ENTER and use the arrow keys to select between Main Link, Sub Link and CLEAR. < P E R F O R M A N C E > M A I N L I N K D I S P Press the arrow keys to browse the error counts for CRC4 Cnt, CURR ES, CURR UAS, etc. To exit the performance display, press ESC. To clear the data registers, press ENTER on the Reset page. Refer to Table 5-3 in Chapter 5 TEST and DIAGNOSTICS, for the meaning of the performance messages. This completes the detailed discussion of the function setup of the ETU02-MUX via the front panel LCD display. 32

33 Chapter 4. Console Port Operation 4-1 General Chapter 4. Console Port Operation The ETU02-MUX ConsolePort (labeled RS-232/Alarm on the rear panel) is a serial terminal port designed to facilitate setup of all parameters through the use of a standard text based terminal or any terminal emulation program running on a Personal Computer. 4-2 Terminal Connection A notebook computer has become an invaluable tool of the Systems Engineer. Connection to the computer is very straight forward. The only other hardware required is a DB9-pin one-toone, male to female cable. The ETU02-MUX acts as a DCE to the PC s DTE communications port. A convenient application, provided with the Microsoft Windows 98/NT/2K operating systems, is HyperTerminal. Set the properties to match the ETU02-MUX control port defaults as follows: Baud=9600, Data bits=8, Parity=None, Stop bits=1, and handshaking =none. Make the appropriate connections, start the terminal application, apply power to the ETU02-MUX, then press ENTER on the PC keyboard. If you are using HyperTerminal the display should look like the following. Figure 4-1. Example of terminal display Note: When a terminal connection is made to the ETU02-MUX, the front panel LCD will be locked out and display. * C O N T R O L P O R T * C O N N E C T E D > > > > > 33

34 Chapter 4. Console Port Operation 4-3 Menu System Detail The menu systems are displayed in the same order and with the same parameters as those in the LCD display. The following section will detail actual displays with descriptions of parameter settings via relevant key commands. This is the first screen seen after connecting. Note that the first two items, Display and define deal with all the system settings. The Display item will browse settings for viewing only, while under Define, all parameters may be both viewed and changed. ******************************************** **** CTC UNION TECHNOLOGIES CO.,LTD **** **** ETU-02/SNMP TERMINAL MODE **** **** SETUP MENU Ver **** ******************************************** 1. Display System Status. 2. Define System Parameter. 3. Test Function Parameter. 4. Password 5. Reset Data to Default. 6. EXIT DATE : 2002/05/07 TIME : 09:20:01 Enter 1-6 to select function. Enter 1 to enter the Display System Status menu. << Display System Status >> 1. Timing 2. Main Link 3. Sub Link 4. Time Slot 5. Data Port 6. Control Port 7. Alarm Buffer 8. BERT Test Result 9. Performance A. SNMP Agent Information B. ETU-02 Information Enter 1-B or Press "ESC" to previous menu. 34

35 Chapter 4. Console Port Operation Enter 1 to display the Timing Parameters. << Display Timing Parameter >> Master Timing : MAIN LINK BacK Timing : INT OSC Press "ESC" to previous menu. The display shows that the Master Timing is derived from the main E1 link, while the fallback timing, if required, will be derived from the internal oscillator. To exit this menu to the previous one, Enter ESC. << Display System Status >> 1. Timing 2. Main Link 3. Sub Link 4. Time Slot 5. Data Port 6. Control Port 7. Alarm Buffer 8. BERT Test Result 9. Performance A. SNMP Agent Information B. ETU-02 Information Enter 1-B or Press "ESC" to previous menu. Enter 2 to display the settings for the main E1 link. << Display Main Link Parameter >> Frame : CCS CRC-4 : OFF Idle Code : 7E RAI : DISABLE Line Code : HDB3 Impedance : 120 ohm Remote Loop: OFF Press "ESC" to previous menu. The above display shows the settings for Frame type, CRC setting, Idle code, RAI setting, Line Code and E1 interface impedance for the main E1 link. To return to the previous display, enter ESC. 35

36 Chapter 4. Console Port Operation << Display System Status >> 1. Timing 2. Main Link 3. Sub Link 4. Time Slot 5. Data Port 6. Control Port 7. Alarm Buffer 8. BERT Test Result 9. Performance A. SNMP Agent Information B. ETU-02 Information Enter 1-B or Press "ESC" to previous menu. To display the parameter settings for the E1 sub-link, enter 3. << Display Sub Link Parameter >> Frame : CCS CRC-4 : OFF Idle Code : 7E RAI : DISABLE Line Code : HDB3 Impedance : 120 ohm Remote Loop: OFF Press "ESC" to previous menu. This display has shown the settings for Frame type, CRC setting, Idle code, RAI setting, Line Code and E1 interface impedance for the E1 sub-link. To return to the previous display, enter ESC. 36

37 Chapter 4. Console Port Operation To display the Time Slot mapping details, enter 4. << Display Time Slot Mapping >> SLOT : TYPE : Fr C1 C1 C1 C1 C1 C1 C1 SLOT : TYPE : C2 C2 C2 C2 C2 C2 C2 C2 SLOT : TYPE : C3 C3 C3 C3 C3 C3 C3 C3 SLOT : TYPE : C4 C4 C4 C4 C4 C4 C4 C4 NC: No define C(1~4): Channel (1~4) SD: Sub Link Data SV: Sub Link Voice Fr: Framing Si: Signaling Press "ESC" to previous menu. The Time Slot mapping display shows the assignments for all of the 32 timeslots of the E1 frame. All timeslots 0~31 are shown with the assigned abbreviations shown directly beneath. To return to the previous display, enter ESC. To display the Data Port parameter settings for each channel module, enter 5. << Display Data Port Parameter >> PORT TYPE CLOCK MULTI CTS SPEED TC RC 1 V.35 DCE N64 ON 448Kbps NORMAL NORMAL 2 V.35 DCE N64 ON 512Kbps NORMAL NORMAL 3 V.35 DCE N64 ON 512Kbps NORMAL NORMAL 4 V.35 DCE N64 ON 512Kbps NORMAL NORMAL Press "ESC" to previous menu. Enter ESC to return to the Display System Status menu. 37

38 Chapter 4. Console Port Operation Enter 6 to display the Control Port settings. << Display Control Port Parameter >> SPEED : 9600bps DATA : 8 PARITY: NONE Press "ESC" to previous menu. The display shows the current settings. To return to the main display press ESC. Enter 9 to display the Performance data of the ETU-02. << Display E1 Link Performance >> Main Link Performance Current CRC-4 error count : 0 Current errored seconds (ES) : 0 Current unavailable seconds (UAS) : 0 Long term errored seconds (ES) : 0 Long term fail seconds (UAS) : Sub Link Performance Current CRC-4 error count : 0 Current errored seconds (ES) : 0 Current unavailable seconds (UAS) : 0 Long term errored seconds (ES) : 0 Long term fail seconds (UAS) : 0 Current seconds : 766 Long term seconds : 2 Press "ESC" to previous menu or "SPACE" to review, "Enter" to clear. The performance data is listed for both main and sub E1 links. To return to the main display press ESC. 38

39 Chapter 4. Console Port Operation Enter A to display the SNMP agent information. << SNMP Card Information >> Local IP Address : < > Gateway IP Address : < > Subnet Mask Address : < > Community String : <Public> Agent IP Address : < > Access Permission : <Read/Write> Receiver IP Address : < > Severity Status : <Information> Hardware Address : < > Press "ESC" to previous menu. Enter B to display the ETU02 Information screen. << Display ETU-02 Information >> EPLD Version : 01 FPGA Version : 06 DATE : 2002/05/07 TIME : 09:22:21 Press "ESC" to previous menu. The information displayed shows the hardware version numbers of the EPLD and FPGA chips in the ETU-02. To exit this display, press ESC. Then press ESC again to go to the very top menu display. 39

40 Chapter 4. Console Port Operation ******************************************** **** CTC UNION TECHNOLOGIES CO.,LTD **** **** ETU-02/SNMP TERMINAL MODE **** **** SETUP MENU Ver **** ******************************************** 1. Display System Status. 2. Define System Parameter. 3. Test Function Parameter. 4. Password 5. Reset Data to Default. 6. EXIT DATE : 2002/05/07 TIME : 09:25:01 Enter 1-6 to select function. Now we will look at setting up the system parameters. To do this enter 2. << Define System Parameter >> 1. Timing 2. Main Link 3. Sub Link 4. Time Slot 5. Data Port 6. Date & Time 7. SNMP Agent Setup Enter 1-7 or Press "ESC" to previous menu. The first selection of system parameters is the Timing parameter, so let s enter 1. << Define Timing Parameter >> 1. Master Timing 2. Back Timing Enter 1-2 or Press "ESC" to previous menu. There are two timing parameters that can be setup. The "Master Timing" provides the clock source for the ETU02-MUX. If that timing source should fail, a second "Backup Timing" source will be used. Normally, the backup timing would be set to the ETU02-MUX's internal oscillator. 40

41 Chapter 4. Console Port Operation To define the master timing, enter 1. << Define Master Timing Parameter >> Master Timing : MAIN LINK 1. Main Link 2. Sub Link 3. INT OSC 4. Channel 1 5. Channel 2 6. Channel 3 7. Channel 4 Enter 1-7 or Press "ESC" to previous menu. The display shows that the master timing is currently derived from the Main link. To change, select one of the appropriate choices from 1~7 or to exit without changing press ESC. << Define Timing Parameter >> 1. Master Timing 2. Back Timing Enter 1-2 or Press "ESC" to previous menu. To define the fallback timing, enter 2. << Define Back Timing Parameter >> BacK Timing : INT OSC 1. Main Link 2. Sub Link 3. INT OSC Enter 1-3 or Press "ESC" to previous menu. The display shows that the fallback timing is currently derived from the internal oscillator. To change, select one of the appropriate choices from 1~3 or to exit without changing press ESC. << Define Timing Parameter >> 1. Master Timing 2. Back Timing Enter 1-2 or Press "ESC" to previous menu. Enter ESC to leave the Timing Parameter menu and return to Defining System Parameters. 41

42 Chapter 4. Console Port Operation << Define System Parameter >> 1. Timing 2. Main Link 3. Sub Link 4. Time Slot 5. Data Port 6. Date & Time 7. SNMP Agent Setup Enter 1-7 or Press "ESC" to previous menu. To define system parameters for the main E1 link, enter 2. << Define Main Link Parameter >> 1. FRAME 2. CRC-4 3. IDLE CODE 4. RAI 5. LINE CODE 6. REMOTE LOOP FUNCTION Enter 1-6 or Press "ESC" to previous menu. To define the Frame type for the main E1 link, press 1. << Define Main Link Frame Parameter >> Frame : CCS 1. CCS 2. CAS 3. UNFRAME Enter 1-3 or Press "ESC" to previous menu. The current frame type setting is CCS. To change it enter 1~3. To exit and leave the setting unchanged, press ESC. << Define Main Link Parameter >> 1. FRAME 2. CRC-4 3. IDLE CODE 4. RAI 5. LINE CODE 6. REMOTE LOOP FUNCTION Enter 1-6 or Press "ESC" to previous menu. 42

43 Chapter 4. Console Port Operation To enable or disable the CRC-4 setting, enter 2. << Define Main Link CRC-4 Parameter >> CRC-4 : OFF 1. OFF 2. ON Enter 1-2 or Press "ESC" to previous menu. The current setting for CRC-4 is Off. To turn on, press 2. To exit without changing, press ESC. << Define Main Link Parameter >> 1. FRAME 2. CRC-4 3. IDLE CODE 4. RAI 5. LINE CODE 6. REMOTE LOOP FUNCTION Enter 1-6 or Press "ESC" to previous menu. To define the Idle code for the main E1 link, enter 3. << Define Main Link Idle Code >> Idle Code : 7E Enter Code (00~FF) : Enter the new Idle code with the hex value 00~FF, or to exit, press ESC. << Define Main Link Parameter >> 1. FRAME 2. CRC-4 3. IDLE CODE 4. RAI 5. LINE CODE 6. REMOTE LOOP FUNCTION Enter 1-6 or Press "ESC" to previous menu. 43

44 Chapter 4. Console Port Operation To enable or disable the Remote Alarm Indicator, press 4. << Define Main Link RAI Parameter >> RAI : DISABLE 1. Disable 2. Enable Enter 1-2 or Press "ESC" to previous menu. Press 1 to disable, 2 to enable RAI, or press ESC to exit without changing. << Define Main Link Parameter >> 1. FRAME 2. CRC-4 3. IDLE CODE 4. RAI 5. LINE CODE 6. REMOTE LOOP FUNCTION Enter 1-6 or Press "ESC" to previous menu. To change the Line Code press 5. << Define Line Code Parameter >> 1. HDB3 2. AMI Enter 1-2 or Press "ESC" to previous menu. Press 1 to define a Line Code of HDB3, press 2 to define a Line Code of AMI or press ESC to exit without saving. << Define Main Link Parameter >> 1. FRAME 2. CRC-4 3. IDLE CODE 4. RAI 5. LINE CODE 6. REMOTE LOOP FUNCTION Enter 1-6 or Press "ESC" to previous menu. 44

45 Chapter 4. Console Port Operation Press 6 to enter the main link Remote loop back function. << Define Remote Loopback Parameter >> Remote Loop: OFF 1. OFF 2. ON Enter 1-2 or Press "ESC" to previous menu. Press "2" to initiate a remote loop back of the main E1 link, press "1" to stop loop back, or press "ESC" to return to the previous menu without any change. Press ESC again to return to the top of the System Define menu. << Define System Parameter >> 1. Timing 2. Main Link 3. Sub Link 4. Time Slot 5. Data Port 6. Date & Time 7. SNMP Agent Setup Enter 1-7 or Press "ESC" to previous menu. 45

46 Chapter 4. Console Port Operation To define system parameters for the E1 sub-link, enter 3. << Define Sub Link Parameter >> 1. FRAME 2. CRC-4 3. IDLE CODE 4. RAI 5. LINE CODE Enter 1-5 or Press "ESC" to previous menu. As you can see, the parameters for sub-link are identical to the Main Link parameters, but without the "REMOTE LOOP FUNCTION". Press ESC. Refer to the Main Link parameters as a guide for setting the sub-link. << Define System Parameter >> 1. Timing 2. Main Link 3. Sub Link 4. Time Slot 5. Data Port 6. Date & Time 7. SNMP Agent Setup Enter 1-7 or Press "ESC" to previous menu. 46

47 Chapter 4. Console Port Operation To define the Timeslot mapping assignments, press 4. << Define Time Slot Mapping >> TIME SLOT 01 TYPE : Channel 1 1. NC 2. Channel 1 3. Channel 2 4. Channel 3 5. Channel 4 6. Sub Link Data 7. Sub Link Voice Enter 1-7 or Press "ENTER" to next Time Slot or "ESC" to previous menu. The time slot number and assigned type are shown. Select 1~7 as appropriate, press ENTER to move on to the next timeslot or ESC to exit the mapping function. If we press the ENTER key now, the second timeslot will be displayed. << Define Time Slot Mapping >> TIME SLOT 02 TYPE : Channel 1 1. NC 2. Channel 1 3. Channel 2 4. Channel 3 5. Channel 4 6. Sub Link Data 7. Sub Link Voice Enter 1-7 or Press "ENTER" to next Time Slot or "ESC" to previous menu. Continue to set the timeslot mapping assignments for all 31 timeslots or ESC. This will take us back to the System Parameter menu. << Define System Parameter >> 1. Timing 2. Main Link 3. Sub Link 4. Time Slot 5. Data Port 6. Date & Time 7. SNMP Agent Setup Enter 1-7 or Press "ESC" to previous menu. 47

48 Chapter 4. Console Port Operation Press 5 to define the Data port parameters. << Define Data Port Parameter >> 1. Channel 1 2. Channel 2 3. Channel 3 4. Channel 4 Enter 1-4 or Press "ESC" to previous menu. Press the appropriate number 1~4 corresponding to the Data Port channel to be defined. Here is an example for setting channel 1. (Note: The two channel Mux will only display channels 1 and 2.) << Define Channel 1 Parameter >> PORT TYPE CLOCK MULTI. CTS SPEED TC RC 1 V.35 DCE N64 ON 448Kbps NORMAL NORMAL 1. Clock Mode 2. Multiplier 3. CTS 4. TC Output 5. RC Output Enter 1-5 or Press "ESC" to previous menu. Press 1 to define the clock mode for the selected channel. << Define Channel 1 Clock Mode >> 1. DCE 2. DTE1 3. DTE2 4. DTE3 Enter 1-4 or Press "ESC" to previous menu. Choose the desired clock mode or ESC to the channel selection menu. << Define Data Port Parameter >> 1. Channel 1 2. Channel 2 3. Channel 3 4. Channel 4 Enter 1-4 or Press "ESC" to previous menu. 48

49 Chapter 4. Console Port Operation Now we will select Channel 2 for setting, press 2. << Define Channel 2 Parameter >> PORT TYPE CLOCK MULTI. CTS SPEED TC RC 1 V.35 DCE N64 ON 512Kbps NORMAL NORMAL 1. Clock Mode 2. Multiplier 3. CTS 4. TC Output 5. RC Output Enter 1-5 or Press "ESC" to previous menu. Press item 2 to set the channel multiplier. << Define Channel 2 Multiplier Parameter >> 1. N64 2. N56 Enter 1-2 or Press "ESC" to previous menu. Press 1 to enter n64 multiplier, 2 to enter n56 multiplier or ESC to leave unchanged. << Define Data Port Parameter >> 1. Channel 1 2. Channel 2 3. Channel 3 4. Channel 4 Enter 1-4 or Press "ESC" to previous menu. Now we will select Channel 3 and set the CTS parameter. Press 3. << Define Channel 3 Parameter >> PORT TYPE CLOCK MULTI. CTS SPEED TC RC 1 V.35 DCE N64 ON 512Kbps NORMAL NORMAL 1. Clock Mode 2. Multiplier 3. CTS 4. TC Output 5. RC Output Enter 1-3 or Press "ESC" to previous menu. 49

50 Chapter 4. Console Port Operation Press 3 to modify the CTS setting. << Define Channel 3 CTS Parameter >> 1. ON 2. RTS Enter 1-2 or Press "ESC" to previous menu. Enter the appropriate setting for CTS or press ESC to exit without changing. << Define Data Port Parameter >> 1. Channel 1 2. Channel 2 3. Channel 3 4. Channel 4 Enter 1-4 or Press "ESC" to previous menu. Now we will select Channel 4 and set the TC Output parameter. Press 4. << Define Channel 4 Parameter >> PORT TYPE CLOCK MULTI. CTS SPEED TC RC 1 V.35 DCE N64 ON 512Kbps NORMAL NORMAL 1. Clock Mode 2. Multiplier 3. CTS 4. TC Output 5. RC Output Enter 1-5 or Press "ESC" to previous menu. Press 4 to modify the TC Output polarity. << Define Channel 4 TC Parameter >> 1. NORMAL 2. INVERT Enter 1-2 or Press "ESC" to previous menu. Enter the appropriate setting for TC signal polarity, normal or inverted or press ESC to exit without changing. 50

51 Chapter 4. Console Port Operation << Define Data Port Parameter >> 1. Channel 1 2. Channel 2 3. Channel 3 4. Channel 4 Enter 1-4 or Press "ESC" to previous menu. Now we will select Channel 4 and set the RC Output parameter. Press 4. << Define Channel 4 Parameter >> PORT TYPE CLOCK MULTI. CTS SPEED TC RC 1 V.35 DCE N64 ON 512Kbps NORMAL NORMAL 1. Clock Mode 2. Multiplier 3. CTS 4. TC Output 5. RC Output Enter 1-5 or Press "ESC" to previous menu. Press 5 to modify the RC Output polarity. << Define Channel 4 RC Parameter >> 1. NORMAL 2. INVERT Enter 1-2 or Press "ESC" to previous menu. Enter the appropriate setting for RC signal polarity, normal or inverted or press ESC to exit without changing. Press ESC again to exit to the Define System Parameter. << Define System Parameter >> 1. Timing 2. Main Link 3. Sub Link 4. Time Slot 5. Data Port 6. Date & Time 7. SNMP Agent Setup Enter 1-7 or Press "ESC" to previous menu. 51

52 Chapter 4. Console Port Operation The following is an example of setting the system date and time into the unit's real-time clock. Press 6. << Define Date & Time >> 1. DATE 2. TIME DATE : 2002/05/07 TIME : 09:30:25 Enter 1-2 or Press "ESC" to previous menu. To define the Date, press 1. Enter the 4 digit year, followed by the month (single digit months must have a leading zero) and complete with the day (single digit days must have a leading zero). << Define Date >> YEAR (1900 ~ 2099) : 2002 MONTH ( 01 ~ 12 ) : 05 DAY ( 01 ~ 31 ) : 07 Following entry of the Date, the screen will revert to the Define Date & Time screen. To define the time, press 2. << Define Time >> HOUR (00 ~ 23) : 09 MINUTE (00 ~ 59) : 31 SECOND (00 ~ 59) : 00 Enter the Hour (24 hour format), Minutes, and Seconds. (Single digit entries must have a leading zero.) << Define Date & Time >> 1. DATE 2. TIME DATE : 2002/05/07 TIME : 09:31:04 Enter 1-2 or Press "ESC" to previous menu. To return to the upper level menu, press ESC. 52

53 Chapter 4. Console Port Operation << Define System Parameter >> 1. Timing 2. Main Link 3. Sub Link 4. Time Slot 5. Data Port 6. Date & Time 7. SNMP Agent Setup Enter 1-7 or Press "ESC" to previous menu. Note: For setting of the SNMP Agent, please refer to Chapter 6 on SNMP. Press ESC again to reach the top level menu. We will move on to setting the Test Function parameters. From the top menu, press 3. << Define Test Mode Function >> 1. LoopBack Test 2. Bert Test Enter 1-2 or Press "ESC" to previous menu. First we will look at the item Loop back Test, press 1. << Define LoopBack Test Port >> Main Link LoopBack: LOOPBACK OFF Sub Link LoopBack: LOOPBACK OFF Channel 1 LoopBack: LOOPBACK OFF Channel 2 LoopBack: LOOPBACK OFF Channel 3 LoopBack: LOOPBACK OFF Channel 4 LoopBack: LOOPBACK OFF 1. Main Link 2. Sub Link 3. Channel 1 4. Channel 2 5. Channel 3 6. Channel 4 7. All Channel LoopBack OFF Enter 1-7 or Press "ESC" to previous menu. The first three lines of the display show the current loop back status of the Main and Sub E1 links as well as the four Data Channels. In the next example we will set loop back type for the Main Link. Press 1. 53

54 Chapter 4. Console Port Operation << Main Link LoopBack >> Main Link LoopBack : LOOPBACK OFF 1. OFF 2. Local Analog Loopback 3. Local Digital Loopback 4. Local Payload Loopback 5. Remote Analog Loopback 6. Remote Payload Loopback Enter 1-6 or Press "ESC" to previous menu. The choices presented are to turn OFF loop back or turn ON Local or Remote loop back. In the following example you will observe that the loop back will change to Local Analog. Press 2. << Main Link LoopBack >> Main Link LoopBack : LOCAL ANALOG 1. OFF 2. Local Analog Loopback 3. Local Digital Loopback 4. Local Payload Loopback 5. Remote Analog Loopback 6. Remote Payload Loopback Enter 1-6 or Press "ESC" to previous menu. If we now ESC back, the display of all loop back status can be observed. Note that the Main Link is now set for Local Analog. << Define LoopBack Test Port >> Main Link LoopBack: LOCAL ANALOG Sub Link LoopBack : LOOPBACK OFF Channel 1 LoopBack: LOOPBACK OFF Channel 2 LoopBack: LOOPBACK OFF Channel 3 LoopBack: LOOPBACK OFF Channel 4 LoopBack: LOOPBACK OFF 1. Main Link 2. Sub Link 3. Channel 1 4. Channel 2 5. Channel 3 6. Channel 4 7. All Channel LoopBack OFF Enter 1-7 or Press "ESC" to previous menu. (Refer to Chapter 5, Test and Diagnostics for detailed explanation of all loop back modes for use with an external Bit Error Rate Tester or the unit's internal BERT.) 54

55 Chapter 4. Console Port Operation Now we will select the Main Link again (Press 1) and turn OFF loopback. << Main Link LoopBack >> Main Link LoopBack : LOCAL ANALOG 1. OFF 2. Local Analog Loopback 3. Local Digital Loopback 4. Local Payload Loopback 5. Remote Analog Loopback 6. Remote Payload Loopback Enter 1-6 or Press "ESC" to previous menu. Press 1 to turn Off loopback. << Main Link LoopBack >> Main Link LoopBack : LOOPBACK OFF 1. OFF 2. Local Analog Loopback 3. Local Digital Loopback 4. Local Payload Loopback 5. Remote Analog Loopback 6. Remote Payload Loopback Enter 1-6 or Press "ESC" to previous menu. Press ESC and the status will again be displayed. << Define LoopBack Test Port >> Main Link LoopBack: LOOPBACK OFF Sub Link LoopBack: LOOPBACK OFF Channel 1 LoopBack: LOOPBACK OFF Channel 2 LoopBack: LOOPBACK OFF Channel 3 LoopBack: LOOPBACK OFF Channel 4 LoopBack: LOOPBACK OFF 1. Main Link 2. Sub Link 3. Channel 1 4. Channel 2 5. Channel 3 6. Channel 4 7. All Channel LoopBack OFF Enter 1-7 or Press "ESC" to previous menu. 55

56 Chapter 4. Console Port Operation Now we will setup a loop back to use in the BERT setting example that follows. Enter 6 for channel 4 loop back. << Channel 4 LoopBack >> Channel 4 LoopBack : LOOPBACK OFF 1. OFF 2. Local Analog Loopback 3. Local Digital Loopback 4. V.54 Loopback Enter 1-4 or Press "ESC" to previous menu. The choices presented are to turn OFF loop back or turn ON Local or Remote loop back. In the following example you will observe that the loop back will change to V.54 Loopback. Press 4. << Channel 4 LoopBack >> Channel 4 LoopBack : V.54 LOOP 1. OFF 2. Local Analog Loopback 3. Local Digital Loopback 4. V.54 Loopback Enter 1-4 or Press "ESC" to previous menu. If we now ESC back, the display of all loop back status can be observed. Note that the Main Link is now set for Local Analog. << Define LoopBack Test Port >> Main Link LoopBack: LOOPBACK OFF Sub Link LoopBack : LOOPBACK OFF Channel 1 LoopBack: LOOPBACK OFF Channel 2 LoopBack: LOOPBACK OFF Channel 3 LoopBack: LOOPBACK OFF Channel 4 LoopBack: V.54 LOOP 1. Main Link 2. Sub Link 3. Channel 1 4. Channel 2 5. Channel 3 6. Channel 4 7. All Channel LoopBack OFF Enter 1-7 or Press "ESC" to previous menu. Press ESC to back out to the Define Test Mode menu. 56

57 Chapter 4. Console Port Operation << Define Test Mode Function >> 1. LoopBack Test 2. Bert Test Enter 1-2 or Press "ESC" to previous menu. Select item 2 to define the BERT test. The display shows that BERT function is OFF but is set to run on Channel 1 with the 511 pattern by default. << Bert Test Parameter >> Function : OFF Pattern : 511 Channel : CH1 Error Insert : NONE 1. Function 2. Channel 3. Pattern 4. Error Insert 5. Result Enter 1-5 or Press "ESC" to previous menu. To start BERT function, select item 1. << Bert Test Function >> Function : OFF 1. OFF 2. ON Enter 1-2 or Press "ESC" to previous menu. Enter 2 to Start the BERT function. Enter 1 to Stop BERT function. The next screen will show the function status if 2 is selected. << Bert Test Function >> Function : ON 1. OFF 2. ON Enter 1-2 or Press "ESC" to previous menu. Press ESC. 57

58 Chapter 4. Console Port Operation Here are the results. << Bert Test Parameter >> Function : ON Pattern : 511 Channel : CH1 Error Insert : NONE 1. Function 2. Channel 3. Pattern 4. Error Insert 5. Result Enter 1-5 or Press "ESC" to previous menu. Now we will select a different channel for BERT testing. Press 2. << Bert Test Channel >> Channel : CH1 1. Channel 1 2. Channel 2 3. Channel 3 4. Channel 4 5. Sub Link to Main Link 6. Sub Link to Sub Link Enter 1-6 or Press "ESC" to previous menu. Enter 4, to select channel 4 for testing. << Bert Test Channel >> Channel : CH4 1. Channel 1 2. Channel 2 3. Channel 3 4. Channel 4 5. Sub Link to Main Link 6. Sub Link to Sub Link Enter 1-6 or Press "ESC" to previous menu. 58

59 Chapter 4. Console Port Operation After pressing ESC, the parameter screen will show again. << Bert Test Parameter >> Function : ON Pattern : 511 Channel : CH4 Error Insert : NONE 1. Function 2. Channel 3. Pattern 4. Error Insert 5. Result Enter 1-5 or Press "ESC" to previous menu. The default pattern is "511", to select a different pattern for testing. Enter 3. << Bert Test Pattern >> Pattern : e e QRSS 6. 2e ALL 1 8. ALL 0 9. ALT A B. 3in24 C. 1in16 D. 1in8 E. 1in4 Enter 1-E or Press "ESC" to previous menu. 59

60 Chapter 4. Console Port Operation In this example, we will enter 4, to select the 2e20-1 pattern. << Bert Test Pattern >> Pattern : ALT e e QRSS 6. 2e ALL 1 8. ALL 0 9. ALT A B. 3in24 C. 1in16 D. 1in8 E. 1in4 Enter 1-E or Press "ESC" to previous menu. Press ESC. Note in the screen below, the function is ON, channel is CH4 and pattern is 2e20-1. << Bert Test Parameter >> Function : ON Channel : CH4 Pattern : 2e20-1 Error Insert : NONE 1. Function 2. Channel 3. Pattern 4. Error Insert 5. Result Enter 1-5 or Press "ESC" to previous menu. 60

61 Chapter 4. Console Port Operation An important function of BERT is the ability to insert errors at a pre-defined error rate or to insert single bit errors on command. Press 4. << Bert Test Error Insert >> Error Insert : NONE 1. NONE 2. SINGLE 3. 10e e e e e e e-7 Enter 1-9 or Press "ESC" to previous menu. Press 2, to insert single errors on command. << Bert Test Error Insert >> Press "ENTER" to insert single error or "ESC" to previous menu With each press of the ENTER key, one error will be inserted. << Bert Test Error Insert >> Press "ENTER" to insert single error or "ESC" to previous menu Press ENTER inserts another error. Press ESC. << Bert Test Error Insert >> Press "ENTER" to insert single error or "ESC" to previous menu 61

62 Chapter 4. Console Port Operation << Bert Test Error Insert >> Error Insert : SINGLE 1. NONE 2. SINGLE 3. 10e e e e e e e-7 Enter 1-9 or Press "ESC" to previous menu. In addition, the error insert rate may be set from 10-7 to Press ESC again to the Parameter screen. << Bert Test Parameter >> Function : ON Channel : CH4 Pattern : 2e20-1 Error Insert : SINGLE 1. Function 2. Channel 3. Pattern 4. Error Insert 5. Result Enter 1-5 or Press "ESC" to previous menu. To view the Results of BERT testing, press 5. << Display BERT Test Results >> Rx Bit: Rx Error Bit: 7 Rx Error Rate: 2.7e-07 Press "ESC" to previous menu or "SPACE" to review, "ENTER" to clear. Press "Enter" to reset the counters, "SPACE" will refresh the display. After viewing the BERT results, press ESC. << Bert Test Parameter >> Function : ON Channel : CH4 Pattern : 2e20-1 Error Insert : SINGLE 1. Function 2. Channel 3. Pattern 4. Error Insert 5. Result Enter 1-5 or Press "ESC" to previous menu. 62

63 Chapter 4. Console Port Operation To turn off the BERT function, call up the function menu. Press 1. << Bert Test Function >> Function : ON 1. OFF 2. ON Enter 1-2 or Press "ESC" to previous menu. Press 1, to turn off BERT. << Bert Test Function >> Function : OFF 1. OFF 2. ON Enter 1-2 or Press "ESC" to previous menu. Press ESC. << Bert Test Parameter >> Function : OFF Channel : CH4 Pattern : 2e20-1 Error Insert : SINGLE 1. Function 2. Channel 3. Pattern 4. Error Insert 5. Result Enter 1-5 or Press "ESC" to previous menu. Press ESC again. << Define Test Mode Function >> 1. LoopBack Test 2. Bert Test Enter 1-2 or Press "ESC" to previous menu. 63

64 Chapter 4. Console Port Operation Press ESC one last time to reach to top level menu. ******************************************** **** CTC UNION TECHNOLOGIES CO.,LTD **** **** ETU-02/SNMP TERMINAL MODE **** **** SETUP MENU Ver **** ******************************************** 1. Display System Status. 2. Define System Parameter. 3. Test Function Parameter. 4. Password 5. Reset Data to Default. 6. EXIT DATE : 2002/05/07 TIME : 10:15:49 Enter 1-6 to select function. The following is an example of Password setting for the ETU02-MUX. Press 4. << Password >> 1. Set Password 2. Clear Password Enter 1-2 or Press "ESC" to previous menu. Enter 1 to set the password. << Entry Password >> Enter Password ( 4 Number ) : Enter *** Password entry successful. *** Press "ESC" to previous menu. Note: If you should ever forget the password, you may clear it with the factory default password, which is: ctcu (any case upper or lower, doesn't matter) Shhh Keep it a secret. 64

65 Chapter 4. Console Port Operation Press ESC. << Password >> 1. Set Password 2. Clear Password Enter 1-2 or Press "ESC" to previous menu. To clear the password, press 2. << Clear Password >> Enter Original Password : Enter the original password, *** Password is DISABLED *** Press "ESC" to previous menu. Press ESC. << Password >> 1. Set Password 2. Clear Password Enter 1-2 or Press "ESC" to previous menu. Press ESC back to main menu. ******************************************** **** CTC UNION TECHNOLOGIES CO.,LTD **** **** ETU-02/SNMP TERMINAL MODE **** **** SETUP MENU Ver **** ******************************************** 1. Display System Status. 2. Define System Parameter. 3. Test Function Parameter. 4. Password 5. Reset Data to Default. 6. EXIT DATE : 2002/05/07 TIME : 10:16:12 Enter 1-6 to select function. 65

66 Chapter 4. Console Port Operation To reset all parameters to the original factory default settings, press 5. ****WARNING***** The reset function is performed without further prompting!!!! All settings including the real time clock are effected. The following will immediately be displayed. If you see this message, the unit has already reset. *** Already Reset Data to Default. *** Press "ESC" to previous menu. Press ESC. ******************************************** **** CTC UNION TECHNOLOGIES CO.,LTD **** **** ETU-02/SNMP TERMINAL MODE **** **** SETUP MENU Ver **** ******************************************** 1. Display System Status. 2. Define System Parameter. 3. Test Function Parameter. 4. Password 5. Reset Data to Default. 6. EXIT DATE : 1999/03/01 TIME : 00:00:05 Enter 1-6 to select function. To exit the terminal mode. press 6. The terminal connection will be dropped and the following will display. ETU-02 TERMINAL MODE IS DISCONNECTED The front panel LCD will return to its normal condition. This completes the detailed examples of terminal mode operation for the ETU02-MUX. 66

67 Chapter 5. Test and Diagnostics Chapter 5. Test and Diagnostics 5-1. General The ETU02-MUX diagnostics functions include: Status indications and messages. User activated loop back. Integrated Bit Error Rate Test (BERT). The loop back tests are activated via the user data port, front panel LCD interface or from the console terminal menu. The ETU02-MUX also offers bit error rate testing on both the synchronous data channel or the E1 sub link, using a locally generated pseudo-random sequence. To provide compatibility with other BERT equipment, you may define the pseudorandom pattern Status Indicators and Messages Indicators: The status of the ETU02-MUX is indicated by viewing the Signal Loss, Sync Loss, Alarm, Error and Test LED indicators. User data channel activity is indicated by the corresponding RD and TD LED indicators. Table 5-1 LED indicators Indicator Color Function PWR Green ON when power is on. Signal Loss Red ON when received signal is lost.(main E1 & sub E1) Sync Loss Red ON when received frame sync is lost.(main E1 & sub E1) Alarm Red ON when main E1 or sub E1 has an alarm. (Includes: BPV (Bipolar Violation) error / CRC4 error / Frame slip / All one / Remote alarm) RD Yellow ON when SPACE is being received.(ch1,ch2,ch3,ch4) Off when MARK is being received. Flashing when data is received. TD Yellow ON when SPACE is being transmitted (CH1,CH2,CH3,CH4) Flashing when data is transmitted. Error Red ON when BERT function is activated and detects bit errors. Test Red ON when the ETU02-MUX is in any loop back mode or BERT function is on. 67

68 Chapter 5. Test and Diagnostics Display: The ETU02-MUX maintains an alarm buffer. The buffer can store one alarm event of each type along with the time of occurrence. A maximum of 256 alarms may be displayed on the front panel or the terminal. Table 5-2 presents the alarm messages generated by the ETU02-MUX. Table 5-2 Alarm Message Message Description Corrective Actions Alarm type POWER Power ON/OFF time. ON/OFF BRG1 FAILURE BRG2 FAILURE BRG3 FAILURE BRG4 FAILURE The data port CH1-CH4 baud rate generator failure. Only tested at power on. Check the clock mode of the responding user data channel. Replace the ETU02-MUX. FIFO1 SLIP The data port CH1-CH4 Check the clock mode of the FIFO2 SLIP FIFO buffer suffered an responding user data channel. FIFO3 SLIP overflow or underflow, Replace the ETU02-MUX. FIFO4 SLIP usually caused by inconsistencies in clock rates. FALLBACK CLK The ETU02-MUX has Check the master clock source: switched to the backup ML-fails when the main link suffers clock source. a loss of signal. CH1, CH2, CH3, CH4-fails when data channel equipment is disconnected or inoperative. SL-fails when the sub link suffers a loss of signal. DATABASE CS The ETU02-MUX Press ENTER to load the default ERR technical failure. The data configuration, resetting all the base currently stored in parameters. the non-volatile memory Perform the power up self test and is corrupted. replace the ETU02-MUX if a failure is detected. SELF TEST ERR A problem has been Replace the ETU02-MUX. detected during power on self-test. ON ON ON/OFF ON/OFF ON 68

69 Chapter 5. Test and Diagnostics ML SIG. LOSS Loss of main link receive signal. ML SYNC LOSS Loss of main link frame sync. ML BPV ERROR Bipolar violations in the main link receive signal. Updated once per second. ML CRC-4 ERROR CRC-4 errors detected in main link receive signal. Updated once per second. ML FRAME SLIP Main link frame slips are detected. Updated once per second. ML AIS Main E1/Datacom link receiving an all ones signal. SL SIG. LOSS Loss of sub link receive signal. SL SYNC LOSS Loss of sub link frame sync. SL BPV ERROR Bipolar violations in the sub link receive signal. Updated once per second. SL CRC-4 ERROR CRC-4 errors detected in sub link receive signal. Updated once per second. Check cable connections to the main ON/OFF link connector. Check other equipment providing the link to the ETU02-MUX. Check cable connections to the main ON/OFF link connector. Check other equipment providing the same frame link to the ETU02-MUX. Replace the ETU02-MUX. Check that line attenuation does not ON exceed that specified for E1 line. Check other equipment providing the same line code to the ETU02-MUX. Check other equipment providing the ON same frame link to the ETU02-MUX. Incorrect selection of master clock ON source. Problem with the equipment connected to the remote end of the link, unstable clock source. Problem with the equipment ON/OFF connected to the remote end of the link. Check cable connections to the sub ON/OFF link connector. Check other equipment providing the link to the ETU02-MUX. Check cable connections to the sub ON/OFF link connector. Check other equipment providing the same frame link to the ETU02-MUX. Replace the ETU02-MUX. Check that line attenuation does not ON exceed that specified for E1 line. Check other equipment providing the same line code to the ETU02-MUX. Check other equipment providing the ON same frame link to the ETU02-MUX. 69

70 Chapter 5. Test and Diagnostics SL FRAME SLIP Sub link frame slips are Incorrect selection of master clock ON detected. Updated once source. per second. Problem with the equipment connected to the remote end of the link, unstable clock source. SL AIS Main link receiving all Problem with the equipment ON/OFF ones signal. connected to the remote end of the link User activated loop back. The ETU02-MUX supports the following types of test loop backs. Main link local analog, digital, and payload loop backs Main link remote analog and payload loop backs Sub link local analog and digital loop backs Sub link remote loop back Channel 1-4 local analog and digital loop backs Channel 1-4 V.54 (remote) loop back The user activated loop back functions are accessed from the LOOPBACK PARAMETER menu. The available test functions are described in the following paragraphs. Main link local analog loop back The Main link local analog loop back is performed by connecting the main link transmit signal to the input of the receive path, as shown in Figure 5-1. This returns the transmit signal of each data port and sub link to the receive path of the same port. Each channel (including sub link) must receive its own transmission. This loop back fully tests the local ETU02-MUX operation and the connections to the local DTEs. During this loop back, the ETU02-MUX main link sends an unframed all ones signal to the remote equipment. Before initiating this loop back, disconnect any LAN cables from the rear panel of any Ethernet interface modules. LOCAL ETU02-MUX User DTE CH1 CH2 CH3 "1" E1 Transmission CH4 SUB LINK MAIN LINK Figure 5-1. Main link local analog loop back 70

71 Chapter 5. Test and Diagnostics Main link local digital loop back The Main link local digital loop back is performed by connecting the main link receive signal to the output of the transmit path, as shown in Figure 5-2. This loop back returns the received signal of the main link back out the transmit path. Each channel (including sub link) on the remote side must receive its own transmission. This loop back enables the remote ETU02- MUX to receive back its transmitted data and confirm the connections to the local ETU02- MUX. LOCAL ETU02-MUX User DTE CH1 CH2 CH3 E1 Transmission CH4 SUB LINK MAIN LINK Figure 5-2. Main link local digital loop back Main link local payload loop back The Main link local payload loop back is performed by connecting the timeslot payload data only (without framing or unused timeslots) from the receive data to the output of the transmit path, as shown in Figure 5-3. This returns the received data of each port on the transmit path to the same port. Each channel (including sub link) must receive its own transmission. This loop back enables the remote ETU02-MUX to receive back its test signals and confirm the connections to the remote DTEs. LOCAL ETU02-MUX User DTE CH1 CH2 CH3 E1 Transmission CH4 SUB LINK MAIN LINK Figure 5-3. Main link local payload loop back 71

72 Chapter 5. Test and Diagnostics Main link remote analog loop back The main link remote analog loop back is performed by sending a loop back code to the remote unit. The remote unit then connects its main link receive signal to the output of the transmit path. This loop back test checks the performance of the local ETU02-MUX, the remote ETU02-MUX and the connections between them, as shown in Figure 5-4. REMOTE ETU02-MUX LOCAL ETU02-MUX Remote Analog LB CH1 CH2 User DTE E1 Transmission MAIN LINK CH3 CH4 SUB LINK Figure 5-4. Main link remote analog loop back Note: The remote loop back codes, also referred to as data link messages, for the ETU02-MUX utilize the 4 spare Sa bits within the framing timeslot (TS0). Therefore, any remote loop back functions, including remote analog loop back (LLB) and remote payload loop back (PLB) are only available when running in framed mode (PCM30 or PCM31). Unframed mode does not support any remote loop back functions. Main link remote payload loop back The main link remote payload loop back is performed by sending a loop back code to the remote unit. The remote unit then connects the main link payload to the output of the transmit path. This loop back test checks the performance of the local ETU02-MUX, the remote ETU02-MUX and the connections between them, as shown in Figure 5-5. REMOTE ETU02-MUX LOCAL ETU02-MUX Remote Payload LB E1 Transmission MAIN LINK CH1 CH2 CH3 CH4 SUB LINK User DTE Figure 5-5. Main link remote payload loop back 72

73 Chapter 5. Test and Diagnostics Sub link local analog loop back The sub link local analog loop back is performed by connecting the sub link transmit signal to the input of the receive path, as shown in Figure 5-6. This loop back test checks the connection to the equipment connected to the local sub link. The test signal is provided by the equipment connected to the local sub link. LOCAL ETU02-MUX User DTE CH1 CH2 CH3 E1 Transmission E1 Transmission CH4 SUB LINK MAIN LINK Figure 5-6. Sub link local analog loop back Sub link local digital loop back The sub link local digital loop back is performed by connecting the sub link receive signal to the output of the transmit path, as shown in Figure 5-7. This loop back is used when testing from the remote equipment and tests the local ETU02-MUX and the connection to the remote equipment. The test signal is provided by the equipment connected to the remote sub link. During this loop back, the ETU02-MUX sub link sends an unframed all ones signal to the equipment connected to the local sub link. LOCAL ETU02-MUX User DTE CH1 CH2 CH3 E1 Transmission CH4 E1 Transmission "1" SUB LINK MAIN LINK Figure 5-7. Sub link local digital loop back 73

74 Chapter 5. Test and Diagnostics Sub link remote loop back The sub link remote loop back is performed by sending a loop back code to the remote unit. The remote unit then connects its sub link transmit signal to the input of the receive path, as shown in Figure 5-8. This loop back test checks the performance of the local ETU02-MUX, the remote ETU02-MUX and the connection between them. During this loop back, the ETU02-MUX sub link sends an unframed all ones signal to the equipment connected to the remote sub link. REMOTE ETU02-MUX LOCAL ETU02-MUX Remote LB CH1 CH2 User DTE E1 Transmission MAIN LINK CH3 CH4 SUB LINK "1" Figure 5-8. Sub link remote loop back Channel 1-4 local analog loop back. The channel local analog loop back is performed by connecting the data channel transmit data (TD) to the input of the receive path (RD), as shown in Figure 5-9. The test signal is provided by the local DTE. LOCAL ETU02-MUX User DTE CH1 CH2 CH3 E1 Transmission CH4 SUB LINK MAIN LINK Figure 5-9. Channel local analog loop back 74

75 Chapter 5. Test and Diagnostics Channel 1-4 local digital loop back. The channel local digital loop back is performed by connecting the local data channel receive data (RD) to the data channel transmit input (TD), as shown in Figure The test signal is provided by the remote user DTE. LOCAL ETU02-MUX User DTE CH1 CH2 CH3 E1 Transmission CH4 SUB LINK MAIN LINK Figure Channel local digital loop back Channel 1-4 V.54 remote loopback. The channel V.54 remote loopback is performed by sending standard V.54 loop back codes to the remote channel unit. The remote unit then connects its local data channel receive data (RD) to the channel transmit input (TD), as shown in Figure This loop back test checks the performance of the local DTE, connection to the ETU02-MUX, the local ETU02-MUX, the connection to the remote ETU02-MUX, the remote ETU02-MUX, the connection to the remote DTE and the remote DTE. The test signal is provided by the local user DTE. REMOTE ETU02-MUX LOCAL ETU02-MUX Channel 1 V.54 LB CH1 CH2 User DTE E1 Transmission MAIN LINK CH3 CH4 SUB LINK Figure Channel V.54 remote loop back 75

76 Chapter 5. Test and Diagnostics Integrated Bit Error Rate Test (BERT). The built-in BERT testing may be performed on one channel at a time. During the test, the local DTE is disconnected and the DSR line is off. An internal pattern generator connects a user selected test sequence to the transmit input of the local data channel interface. To calibrate the system, the user can inject errors at a selectable rate. The receive output is connected to a pattern tester. The tester compares the received and transmitted patterns and detects errors. For a local test (stand alone unit), first enable the main link local analog loop back (or hardwire main link TX connector to RX) to return the data back to the local DTE, as shown in Figure User DTE Generator Tester LOCAL ETU02-MUX CH1 CH2 CH3 "1" E1 Transmission CH4 SUB LINK MAIN LINK Figure BERT for local test (BERT on Channel 1, Main Link analog loop back.) Test Steps: Enable main link analog loop back; From the main menu select "3. Test Function Parameter", then select "1. LoopBack Test", then select "3. Channel 1", and lastly select "2. Local Analog Loopback". Start BERT; From the "Define Test Mode Function" menu, select "2. Bert Test". Select the channel; Enter "2. Channel" and select "1. Channel 1", then "ESC". Select a pattern; Enter "3. Pattern" and select "5. QRSS", then "ESC". Start the function; Enter "1. Function" and select "2. ON", then "ESC". View the results; Enter "5. Result". You may clear the counters by pressing "ENTER" or refresh the display by pressing "SPACE". << Display BERT Test Results >> Rx Bit: Rx Error Bit: 0 Rx Error Rate: 0.0e-00 Press "ESC" to previous menu or "SPACE" to review, "ENTER" to clear. The display shows the total received bits (Rx Bit), the total error bits received (Rx Error Bit), and calculates the error rate (error bits total received bits = Rx Error Rate). 76

77 Chapter 5. Test and Diagnostics For a system test, first enable the main link remote digital loop back or the channel V.54 remote loop back to return the data back to the local DTE, as shown in Figure Generator Tester LOCAL ETU02-MUX CH1 CH2 REMOTE ETU02-MUX CH1 CH2 CH3 CH4 E1 CH3 CH4 SUB LINK MAIN LINK MAIN LINK SUB LINK Figure BERT used for system test Test Steps: Enable channel 1 V.54 Loop; From the main menu select "3. Test Function Parameter", then select "1. LoopBack Test", then select "3. Channel 1", and lastly select "4. V.54 Loopback". Start BERT; From the "Define Test Mode Function" menu, select "2. Bert Test". Select the channel; Enter "2. Channel" and select "1. Channel 1", then "ESC". Select a pattern; Enter "3. Pattern" and select "5. QRSS", then "ESC". Start the function; Enter "1. Function" and select "2. ON", then "ESC". View the results; Enter "5. Result". You may clear the counters by pressing "ENTER" or refresh the display by pressing "SPACE". << Display BERT Test Results >> Rx Bit: Rx Error Bit: 0 Rx Error Rate: 0.0e-00 Press "ESC" to previous menu or "SPACE" to review, "ENTER" to clear. The display shows the total received bits (Rx Bit), the total error bits received (Rx Error Bit), and calculates the error rate (error bits total received bits = Rx Error Rate). Test the link by manually inserting a single error. From the "Bert Test Parameter" menu, enter "4. Error Insert" and select "2. Single". Press "ENTER", then "ESC" twice. View the results by entering "5. Result" and confirm that one single error was entered or added to the Rx Error Bits. 77

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79 Chapter 6. SNMP Operation 6-1 Introduction Chapter 6. SNMP Operation Installation of the SNMP feature should be performed only by qualified service personnel. As with all electronic devices that are powered from an AC line, dangerous voltages may be present inside the unit. The technician should exercise proper care and judgment. Only open the unit for service after disconnecting the unit from the power source. This documentation will explain in detail the proper procedure for installation of the SNMP printed circuit board feature for the ETU02-MUX. This procedure may also required replacement of the operational firmware for older versions of the ETU02-MUX as the older firmware does not support the SNMP card functions. 6-2 Required tools and supplies 1. No.2 Philips head screwdriver 2. thread lock compound (such as Glyptol ) 3. small, flat blade screwdriver (to aid in replacing firmware IC) 6-3 Installation Procedure (Please refer to the attached drawing) 1. Inspect the contents of the SNMP kit. It should contain one(1) SNMP card, three(3) brass standoffs, six(6) 3mm screws, one(1) SNMP connector plate, MIB file floppy diskette or CDROM, and possibly a 32pin EEPROM. 2. From the rear of the unit, disconnect all power, data port, and E1 cabling from the unit. Loosen the two captive thumb-screws located on the lower left and right of the unit. Carefully slide the mother PCB out of the case and place on a flat, clean work area. (Refer to Figure 1.) 3. Remove the SNMP connector cover mounting screws (2) with a Philips head screwdriver. Save these screws for attachment of the new cover plate. DO NOT ATTACH AT THIS TIME. 4. Refer to Figure 2, the mounting detail. Apply thread-lock to three mounting screws and attach the three brass standoffs to the main PCB as shown. The standoffs are to be located on the component side of the main PCB. 5. Install the SNMP pc board by placing the RJ-45 connector side into the rear panel cutout. Align the pins of the SNMP card with the 32pin connector and seat the card. Ensure that no pins are bent and that all pins have been received into the connector socket on the main PCB. 6. Use the remaining 3mm screws to hold down the SNMP card. Do not over tighten, just tighten snug. Apply Gloptol to the hold down screws at your discretion. Refer to the mounting detail Figure Attach the beauty-plate on the rear panel, ensuring the RJ-45 connector and link-led are properly aligned. Use the previously released screws from step 3 above. 8. If the firmware needs to be upgraded, use a flat-blade screwdriver to carefully remove the EEPROM IC from PCB location U7 (refer to Figure 1). Ensure that the pins of the new IC are straight, align the pins with the IC socket and carefully seat the new IC. Excessive force should not be required. Inspect all 32 pins to ensure proper seating and that no pins were inadvertently bent during insertion. 9. If the system firmware has been replaced, a system reset will be required to initialize the system properly. Return the motherboard to the case, tighten the captive thumb-screws and reattach all cables and power. Perform a system reset followed by re-configuration and normal loop back diagnostics. 79

80 Chapter 6. SNMP Operation Figure 6-1 Main PCB removal, ETU-02 MUX Figure 6-2 Mounting Detail 80

81 Chapter 6. SNMP Operation 6-4 SNMP Overview The Simple Network Management Protocol (SNMP) is one of many protocols in the Internet Protocol (IP) suite. SNMP is the protocol recommended specifically for the exchange of management information between hosts residing on IP networks. Network management allows you to monitor and control network devices remotely using conventional computer network technology. The SNMP management functions of the ETU02-MUX are provided by an internal SNMP agent, which utilizes out-of-band communication over standard 10Base-T Ethernet. The SNMP agent is compliant with the SNMPv1 standard. SNMP communication uses the User Datagram Protocol (UDP). UDP is a connectionless transport protocol, part of the IP suite. The SNMP application uses an asynchronous command/response polling protocol and operates at the OSI Layer 7 (Layer 7 is the Application Layer. Other IP applications that operate at this layer are FTP, Telnet, SMTP, etc.). All management traffic is initiated by the SNMP-based network management station. Only the addressed managed entity (agent) answers the polling of the management station (except for trap messages). SNMP Operations The SNMP protocol includes four types of operations: getrequest getnextrequest setrequest trap Command for retrieving specific value of an instance from the managed node. The managed node responds with a getresponse message. Command for retrieving sequentially specific management information from the managed node. The managed node responds with a getresponse message. Command for manipulating the value of an instance within the managed node. The managed node responds with a getresponse message. Management message carrying unsolicited information on extraordinary events (that is, events which occurred not in response to a management operation) reported by the managed node. 81

82 Chapter 6. SNMP Operation The Management Information Base The management information base (MIB) includes a collection of managed objects. Managed objects are defined as parameters that can be managed, such as specific information on device configuring or on performance statistics values. The MIB includes the definitions of relevant managed objects (MIB variables) for the specific node. Various MIB's can be defined for various management purposes, types of equipment, etc. The management data itself is a collection of integer, string and MIB address variables that contain all the information necessary to manage the node. A leaf object s definition includes the range of instances (values) and the "access" rights: Read-only Read-write Write-only Not accessible Instances of an object can be read, but cannot be set. Instances of an object can be read or set. Instances of an object can be set, but cannot be read. Instances of an object cannot be read, nor set. MIB Structure The MIB has an inverted tree-like structure (root over leaves), with each definition of a managed instance forming one leaf, located at the end of a branch of that tree. Each "leaf" in the MIB is reached by a unique path, therefore by numbering the branching points, starting with the top, each leaf can be uniquely defined by a sequence of numbers. The formal description of the managed objects and the MIB structure is provided in a special standardized format, called Abstract Syntax Notation 1, or ASN.1 (pronounced A-S-N dot one). Since the general collection of MIB's can also be organized in a similar structure, under the supervision of the Internet Activities Board (IAB), any parameter included in a MIB that is recognized by the IAB is uniquely defined. To provide the flexibility necessary in a global structure, MIB's are classified in various classes (branches), one of them being the experimental branch, another being the management (mgmt) branch, and yet another the group of private (enterprise-specific) branch. Under the private enterprise-specific branch of MIB's, each enterprise (manufacturer) can be assigned a number, which is its enterprise number. The assigned number designates the top of an enterprise-specific sub-tree of non-standard MIB's. Within this context, CTC Union has been assigned the enterprise number Under this scheme, the path to CTC Union s Enterprise branch would be: iso(1).org(3).dod(6).internet(1).private(4).enterprises(1).ctcu(4756) Enterprise-specific MIB's are published and distributed by their creators, who are responsible for their contents. Specific information regarding the CTC Union s sub-tree are available from CTC Union s Research and Development Division. The MIB supported by the ETU02-MUX SNMP Agent follows RFC 1158 (MIB-II standard). 82

83 Chapter 6. SNMP Operation SNMP Communities To enable the delimitation of management domains, SNMP uses "communities". Each community is identified by a name, which is an alphanumeric string of up to 255 characters defined by the user. Any SNMP entity (this term includes both managed nodes and management stations) is assigned by its user a community name. In parallel, the user defines for each SNMP entity a list of the communities which are authorized to communicate with it, and the access rights associated with each community (this is the SNMP community name table of the entity). In general, SNMP agents support two types of access rights: Read-only Read-write the SNMP agent accepts and processes only SNMP getrequest and getnextrequest commands from management stations which have a read-only community name. the SNMP agent accepts and processes all the SNMP commands received from a management station with a read-write community name. SNMP agents are usually configured to send traps to management stations having read-write communities. 6-5 Configuring the ETU02-MUX SNMP Agent The agent for the ETU02-MUX resides in the SNMP option card installed in the ETU02- MUX. Configuration of the agent is accomplished via the terminal Control Port of the ETU02. From the main menu select "3. Define System Parameter". << Define System Parameter >> 1. Timing 2. Main Link 3. Sub Link 4. Time Slot 5. Data Port 6. Date & Time 7. SNMP Agent Setup Enter 1-7 or Press "ESC" to previous menu. From the "Define System Parameter" menu, select "7. SNMP Agent Setup". 83

84 Chapter 6. SNMP Operation This is the main menu for setting up the SNMP agent in the ETU02. << SNMP Agent Setup Menu >> 1. Set the Agent Information. 2. Set Access Control Table. 3. Set Trap Receivers Table. 4. Set Community String. < Public > 5. Save Parameter to SNMP Card and Exit. Enter 1-5 or Press "ESC" to previous menu. "1. Set the Agent Information" will call the menu for setting the ETU02 SNMP agent information. The "Local IP address" and "Subnet Mask" are assigned to the SNMP agent (card) in the ETU02. The default gateway is for the network where the ETU02 is attached. << Set the Agent Information >> 1. Local IP Address. < > 2. Subnet Mask. < > 3. Gateway IP Address. < > Enter 1-3 or Press "ESC" to previous menu. "2. Set Access Control Table" will call the menu for setting the IP address of the management workstation which will access the ETU02 SNMP and set the access permissions read/write or read only. << Set Access Control Table >> 1. Input Access IP Address. < > 2. Input Access Permission. <Read Only> Enter 1-2 or Press "ESC" to previous menu. "3. Set Trap Receivers Table" will call the menu for setting the IP address of the management workstation which will receive any "trap" messages sent by the ETU02 SNMP. In addition, the severity level of the messages may be set to informational, warning, or severe. In most cases the trap receiver and management workstation are the same. However, the option exists to provide separate addresses, one for management and one for traps. << Set Trap Receiver Table >> 1. Input Receiver IP. < > 2. Input Severity. <Information> Enter 1-2 or Press "ESC" to previous menu. 84

85 Chapter 6. SNMP Operation "4. Set Community String." Will call the menu to set the community string. The default string is "public". << SNMP Agent Setup Menu >> 1. Set the Agent Information. 2. Set Access Control Table. 3. Set Trap Receivers Table. 4. Set Community String. < Public > 5. Save Parameter to SNMP Card and Exit. Enter 1-5 or Press "ESC" to previous menu. ============================================= Input Community String. Input String. (1 to 8 chars ) : "5. Save Parameter to SNMP Card and Exit." will write the configuration data to the SNMP cards EEPROM (non-volatile ram). The settings are then automatically reloaded if power is lost and then restored to the unit. << SNMP Agent Setup Menu >> 1. Set the Agent Information. 2. Set Access Control Table. 3. Set Trap Receivers Table. 4. Set Community String. < Public > 5. Save Parameter to SNMP Card and Exit. Enter 1-5 or Press "ESC" to previous menu. Wait...Config SNMP Card. Wait until the following screen displays. << Define System Parameter >> 1. Timing 2. Main Link 3. Sub Link 4. Time Slot 5. Data Port 6. Date & Time 7. SNMP Agent Setup Enter 1-7 or Press "ESC" to previous menu. 85

86 Chapter 6. SNMP Operation 6-6 MIB detail for ETU02-MUX First Child Second Child Leaf Object AM Set Variables list systementry systemmaster-timing RW 1:masterMAIN-LINK(0) 2:masterSUB-LINK(1) 3:masterINT-OSC(2) 4:masterCH-1-LINK(3) 5:masterCH-2-LINK(4) 6:masterCH-3-LINK(5) 7:masterCH-4-LINK(6) systemback-timing RW 1:backMAIN-LINK(0) 2:backSUB-LINK(1) 3:backINT-OSC(2) main-linkentry main-linkframe RW 1:frame-CCS(0) 2:frame-CAS(1) 3:frame-UNFRAME(2) main-linkcrc-4 RW 1:crc-4-OFF(0) 2:crc-4-ON(1) main-linkidle-code RW 1: (0 255) main-linkrai RW 1:rai-DISABLE(0) 2:rai-ENABLE(1) main-linkline-code RW 1:linecode-HDB3(0) 2:linecode-AMI(1) main-linkimpedance RO 1:impedance-R120(0) 2:impedance-R75(1) sub-linkentry sub-linkframe RW 1:frame-CCS(0) 2:frame-CAS(1) sub-linkcrc-4 RW 1:crc-4-OFF(0) 2:crc-4-ON(1) sub-linkidle-code RW 1: (0 255) sub-linkrai RW 1:rai-DISABLE(0) 2:rai-ENABLE(1) sub-linkline-code RW 1:linecode-HDB3(0) 2:linecode-AMI(1) sub-linkimpedance RO 1:impedance-R120(0) 2:impedance-R75(1) 86

87 Chapter 6. SNMP Operation First Child Second Child Leaf Object AM Set Variables list timeslotentry timeslotts01 RW 1:ts01-NC(0) 2:ts01-CH-1(1) 3:ts01-CH-2(2) 4:ts01-CH-3(3) 5:ts01-CH-4(4) 6:ts01-SUB-DATA(5) 7:ts01-SUB-VOICE(6) timeslotts02 RW 1:ts02-NC(0) 2:ts02-CH-1(1) 3:ts02-CH-2(2) 4:ts02-CH-3(3) 5:ts02-CH-4(4) 6:ts02-SUB-DATA(5) 7:ts02-SUB-VOICE(6) timeslotts03 timeslotts04 timeslotts05 timeslotts06 timeslotts07 timeslotts08 timeslotts09 timeslotts10 timeslotts11 timeslotts12 timeslotts13 timeslotts14 timeslotts15 timeslotts16 timeslotts17 timeslotts18 timeslotts19 timeslotts20 timeslotts21 timeslotts22 timeslotts23 timeslotts24 timeslotts25 same as TS01 same as TS01 same as TS01 same as TS01 same as TS01 same as TS01 same as TS01 same as TS01 same as TS01 same as TS01 same as TS01 same as TS01 same as TS01 same as TS01 same as TS01 same as TS01 same as TS01 same as TS01 same as TS01 same as TS01 same as TS01 same as TS01 same as TS01 87

88 Chapter 6. SNMP Operation First Child Second Child Leaf Object AM Set Variables list timeslotts26 timeslotts27 timeslotts28 timeslotts29 timeslotts30 timeslotts31 same as TS01 same as TS01 same as TS01 same as TS01 same as TS01 same as TS01 dataportentry dataportch1 ch1-multiplier RW 1:multiplierN64(0) 2:multiplierN56(1) ch1-clock-mode RW 1:clockmodeDCE(0) 2:clockmodeDTE1(1) 3:clockmodeDTE2(2) 4:clockmodeDTE3(3) ch1-ctc RW 1:ctsON(0) 2:ctcOFF(1) ch1-tcout RW 1:tcOutNORMAL(0) 2:tcOutINVERT(1) ch1-rcout RW 1:rcOutNORMAL(0) 2:rcOutINVERT(1) ch1-port-type RO 1:prottypeRESERVE(0) 2:prottypeRS-232(1) 3:prottypeET10(2) 4:prottypeX21(3) 5:prottypeG703(4) 6:prottypeV35(5) 7:prottypeRS530(6) 8:prottypeNO-INSERT(7) ch1-speed RO 1:(0 2048) ch1-txclock RO 1:txclockNORMAL(0) 2:txclockINVERT(1) dataportch2 same as dataportch1 same as dataportch1 dataportch3 same as dataportch1 same as dataportch1 dataportch4 same as dataportch1 same as dataportch1 controlportentry 88

89 Chapter 6. SNMP Operation First Child Second Child Leaf Object AM Set Variables list controlportspeed RW 1:speed300BPS(0) 2:speed600BPS(1) 3:speed1200BPS(2) 4:speed2400BPS(3) 5:speed4800BPS(4) 6:speed9600BPS(5) 7:speed19200BPS(6) loopbackentry loopback-main-link RW 1:mainlink-LOOPBACK-OFF(0) 2:mainlink-LOCAL-ANALOG(1) 3:mainlink-LOCAL-DIGITAL(2) 4:mainlink-LOCAL-PAYLOAD(3) 5:mainlink-REMOTE-ANALOG(4) 6:mainlink-REMOTE-PAYLOAD(5) loopback-sub-link RW 1:sublink-LOOPBACK-OFF(0) 2:sublink-LOCAL-ANALOG(1) 3:sublink-LOCAL-DIGITAL(2) 4:sublink-LOCAL-PAYLOAD(3) 5:sublink-REMOTE-ANALOG(4) 6:sublink-REMOTE-PAYLOAD(5) loopback-ch1 RW 1:ch1-LOOPBACK-OFF(0) 2:ch1-LOCAL-ANALOG(1) 3:ch1-LOCAL-DIGITAL(2) 4:ch1-V54-LOOP(3) loopback-ch2 loopback-ch3 loopback-ch4 same as loopback-ch1 same as loopback-ch1 same as loopback-ch1 loopback-all RW 1:none(0) 2:all-LOOPBACK-OFF(1) berttestentry berttestfunction RW 1:functionOFF(0) 2:functionON(1) berttestchannel RW 1:channelCH1(0) 2:channelCH2(1) 3:channelCH3(2) 4:channelCH4(3) 5:channelSL-ML(4) 6:channelSL-SL(5) 89

90 Chapter 6. SNMP Operation First Child Second Child Leaf Object AM Set Variables list berttestpattern RW 1:pattern511(0) 2:pattern2047(1) 3:pattern2e15-1(2) 4:pattern2e20-1(3) 5:patternQRSS(4) 6:pattern2e23-1(5) 7:patternALL1(6) 8:patternALL0(7) 9:pattern0011(8) 10:pattern-3in24(9) 11:pattern-1in16(10) 12:pattern-1in8(11) 13:pattern-1in4(12) berttesterrins RW 1:errinsNONE(0) 2:errinsSINGLE(1) 3:errins10e-1(2) 4:errins10e-2(3) 5:errins10e-3(4) 6:errins10e-4(5) 7:errins10e-5(6) 8:errins10e-6(7) 9:errins10e-7(8) bertresult resultbiterr RO 1:(8) Octets resultbiterrrate NA 1:(8) Octets resultbiterrraterecount RW 1:none (0) 2:recount (1) dateandtimeentry dateset RW 1:(8) Octets timeset RW 1:(8) Octets miscellaneousentry miscellaneouslcd-light RW 1:lcdlightAUTO(0) 2:lcdlightON(1) 3:lcdlightOFF(2) miscellaneousreset-to-default RW 1:resettodefaultOFF(0) 2:resettodefaultON(1) 90

91 Chapter 6. SNMP Operation First Child Second Child Leaf Object AM Set Variables list alarmentry alarmdisplay RW 1:none(0) 2:display(1) alarmclear RW 1:none(0) 2:clear(1) performanceentry performanceclearall RW 1:none(0) 2:clear(1) performancemainlink mainlinkbpv RO (Integer display) mainlinkcrc4 RO (Integer display) mainlinkcurr-es RO (Integer display) mainlinkcurr-uas RO (Integer display) mainlinklong-es RO (Integer display) mainlinklong-uas RO (Integer display) mainlinkcurr-sec RO (Integer display) mainlinklong-sec RO (Integer display) performancesublink sublinkbpv RO (Integer display) sublinkcrc4 RO (Integer display) sublinkcurr-es RO (Integer display) sublinkcurr-uas RO (Integer display) sublinklong-es RO (Integer display) sublinklong-uas RO (Integer display) sublinkcurr-sec RO (Integer display) sublinklong-sec RO (Integer display) ledstatusentry ledstatustest RO 1:testOFF(0) 2:testON(1) errorstatus RO 1:errorOFF(0) 2:errorON(1) subalarmstatus RO 1:subalarmOFF(0) 2:subalarmON(1) subsynclossstatus RO 1:synclossOFF(0) 2:synclossON(1) subsignallossstatus RO 1:subSignallossOFF(0) 2:subSignallossON(1) mainalarmstatus RO 1:mainAlarmOFF(0) 2: mainalarmon(1) 91

92 Chapter 6. SNMP Operation mainsynclossstatus RO 1:mainSYNClossOFF(0) 2:mainSYNClossON(1) mainsignallossstatus RO 1:mainSignallossOFF(0) 2:mainSignallossON(1) Variable 1: Data Port Type code: Reserved RS-232 ET10 X.21 G.703 V.35 RS-530 Not Insert Variable 2: Data Port Speed code: Unit :Kbps N56 NC N64 NC Variable 3: Bert Result transfer format: Text 1 (9) Text 2 (10) Text 3 (11) Text 4 (12) Text 5 (13) Text 6 (14) Text 7 (15) Text 8 (16) Bit Err Byte 5 Byte 4 Byte 3 Byte 2 Byte 1 Byte 0 X X Bit Err Rate 0 0 e X Bit Err is 48 bits, have to transfer to ASCII for display Bit Err Rate just an ASCII text string Variable 4: Date & Time transfer format (BCD code) Text 1 (9) Text 2 (10) Text 3 (11) Text 4 (12) 0. DATE Century (19-20) Year (00-99) Month (01-12) Date (01-31) 1. TIME Hour (00-23) Minute (00-59) Second (00-59) MIB path iso(1).org(3).dod(6).internet(1).private(4).enterprise(1).ctcu(4756).ctcetu02(2) 92

93 Chapter 6. SNMP Operation 6-7 ETU02-MUX Trap Codes Code Error message Error status On/Off 0 Alarm Buffer Empty 0:None 1 Power Turn 1:On 2:Off 2 Main Link Signal Loss 1:On 2:Off 3 Main Link SYNC Loss 1:On 2:Off 4 Main Link AIS 1:On 2:Off 5 Main Link RAI 1:On 2:Off 6 Main Link MRAI 1:On 2:Off 7 Main Link BPV 0:None 8 Main Link Frame Slip 0:None 9 Main Link CRC4 Error 0:None 10 Sub Link Signal Loss 1:On 2:Off 11 Sub Link SYNC Loss 1:On 2:Off 12 Sub Link AIS 1:On 2:Off 13 Sub Link RAI 1:On 2:Off 14 Sub Link MRAI 1:On 2:Off 15 Sub Link BPV 0:None 16 Sub Link Frame Slip 0:None 17 Sub Link CRC4 Error 0:None 18 Channel 1 port FIFO Slip 0:None 19 Channel 2 port FIFO Slip 0:None 20 Channel 3 port FIFO Slip 0:None 21 Channel 4 port FIFO Slip 0:None 22 Channel 1 port Baud Rate Failure 0:None 23 Channel 2 port Baud Rate Failure 0:None 24 Channel 3 port Baud Rate Failure 0:None 25 Channel 4 port Baud Rate Failure 0:None 26 End of Alarm Buffer 0:None Alarm message Transfer format: Text 1 (9) Text 2 (10) Text 3 (11) Text 4 (12) Text 5 (13) Text 6 (14) Text 7 (15) Text 8 (16) Message Type Code On/Off Code Year (BCD) Month (BCD) Date (BCD) Hour (BCD) Minute (BCD) Second (BCD) 93

94 Chapter 6. SNMP Operation Variable 6: LED Status: Parameter Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Test Error Sub Alarm Sub SYNC Sub Signal Main Alarm Main SYNC Main Signal Loss Loss Loss Loss 94

95 Chapter 7. Troubleshooting Instructions Chapter 7. Troubleshooting Instructions In case a problem occurs, check the displayed alarm messages and refer to the Status indication and Message section in Table 5-2. NO. Trouble Symptoms Probable cause Corrective measure 1 PWR indicator off No AC power. Check that both ends of the AC power cable are properly connected. Blown fuse. Replace with fuse of proper rating. Defective ETU02-MUX. Replace the ETU02-MUX. 2 PWR indicator flashes Hardware failure. Replace the ETU02-MUX. 3 MAIN E1 Signal Loss No signal received from Check cable connections to the main indicator on the remote device. link connector. Check other equipment providing the link to the ETU02-MUX. Activate the local analog loop back on the main link. Check if the ETU02- MUX MAIN E1 Sync Loss indicator is off, then the problem is external. Defective ETU02-MUX. Replace the ETU02-MUX. 4 MAIN E1 Sync Loss indicator on Wrong frame format. Check cable connections to the main link connector. Check other equipment providing the same frame link to the ETU02-MUX or reset local ETU02-MUX frame format. Defective ETU02-MUX. Replace the ETU02-MUX. 5 MAIN E1 Alarm indicator on BPV error, Excessive noise on the line from Check that line attenuation does not exceed that specified for E1 line. remote device. Check other equipment providing the same line code to the ETU02-MUX. CRC-4 error. Check other equipment providing the same frame link to the ETU02-MUX. Received AIS signal. Problem at the equipment connector to the remote end of the link. Received RAI or MRAI signal. Problem at the equipment connector to the remote end of the link. 95

96 Chapter 7. Troubleshooting Instructions NO. Trouble Symptoms Probable cause Corrective measure 6 SUB E1 Signal Loss indicator on No signal receive from the remote device. Check cable connections to the sub link connector. Check other equipment providing the link to the ETU02-MUX. Activate the local analog loop back on the sub link. Check if the ETU02-MUX SUB E1 Sync Loss indicator is off, then the problem is external. Defective ETU02-MUX. Replace the ETU02-MUX. 7 SUB E1 Sync Loss indicator on Wrong frame format. Check cable connections to the sub link connector. Check other equipment providing the same frame link to the ETU02-MUX or reset local ETU02-MUX frame format. Defective ETU02-MUX. Replace the ETU02-MUX. 8 SUB E1 Alarm BPV error, Excessive Check that line attenuation does not indicator on noise on the line from the exceed that specified for E1 line. remote device. Check other equipment providing the same line code to the ETU02-MUX. CRC-4 error. Check other equipment providing the same frame link to the ETU02-MUX. Received AIS signal. Problem at the equipment connector to the remote end of the link. Received RAI or MRAI signal. Problem at the equipment connector to the remote end of the link. 96

97 Appendix A. DIP Switch Setting Appendix A. DIP Switch Setting A-1 DSW1 Setting DSW1 STATE FUNCTION CONDITION -1 OFF Reserved ON Reserved -2 OFF Reserved ON Reserved -3 OFF Reserved ON Reserved -4 OFF Reserved ON Reserved -5 OFF Reserved ON Reserved A-2 DSW2 Main E1 Line Impedance Setting DSW2 STATE FUNCTION CONDITION ALL OFF 120 ohm balanced Factory setting ON 75 ohm unbalanced DSW2 is located on the main PC board. A-3 SW1 Sub E1 Line Impedance Setting SW1 STATE FUNCTION CONDITION ALL OFF 120 ohm balanced Factory setting ON 75 ohm unbalanced SW1 are located on the Sub E1 interface card. A-4 Jumper CHASS1 Frame Ground Setting CHASS1 STATE FUNCTION CONDITION ALL DIS Frame ground not connected to signal Factory setting CON Frame ground connected to signal ground CHASS1 is located on the main PC board close to DSW2. 97

98 Appendix A. DIP Switch Setting 98

99 Appendix B. Connections B-1. E1 Line Connectors Appendix B. Connections B-1.1 D-15 connector The E1 link D-15 connector conforms to AT&T Pub The physical interface is a 15-pin female D-type connector. Pin Designation Direction Function 1 TTIP From ETU02-MUX Transmit data 2 FG Frame ground 3 RTIP To ETU02-MUX Receive data 4 FG Frame ground TRING From ETU02-MUX Transmit data RRING To ETU02-MUX Receive data Table B-1 E1 D-15 connector pin allocation B-1.2 BNC connector Conn. Pin Designation Direction Function TX Center TTIP From ETU02- Transmit data MUX Sleeve TRING Signal return RX Center RTIP To ETU02-MUX Receive data Sleeve RRING Signal return Table B-2 E1 BNC connector pin allocation 99

100 Appendix B. Connections B-2. RS-232/Alarm Port Connector The ETU02-MUX RS-232/ALARM port is located on the front panel and has a standard RS-232 DCE interface with a 9-pin female D-type connector, wired in accordance with Table B-8. Pin RS-232 Function Direction Connected to Terminal Alarm Relay function DB9 DB25 1 Data Carrier Detect Output 1 8 (DCD) 2 Receive Data Output 2 3 (RD) 3 Transmit Data (TD) Input Normally closed (NC) 5 Signal Ground Common contact (COM) 7 Request To Sent Input 7 4 (RTS) 8 Clear To Sent (CTS) Output Normally open (NO) Table B-8 RS-232/ALARM port connector pin allocation C-1. X.21 Data Channel Module For applications using an X.21 interface external clock (Clock mode select DTE1 or DTE3), connect the input clock to pins 7(A) and 14(B) of the DB15-pin connector. X.21 Interface, pin assignment SIGNAL PIN CIRCUIT DIRECTION DESCRIPTION FUNCTION 100

101 Appendix C. Interface Modules Protective Ground 1 Shield Chassis ground. May be isolated from Signal Ground. Signal Ground 8 G Common signal ground. Transmitted 2 T(A) To ETU02-MUX Serial digital data from DTE. Data 9 T(B) Received Data 4 11 R(A) R(B) Fm ETU02-MUX Serial digital data at the output of the ETU02-MUX receiver. Request to Sent 3 10 C(A) C(B) To ETU02-MUX An ON signal to the ETU02-MUX when data transmission is desired. Data Carrier Detect 5 12 I(A) I(B) Fm ETU02-MUX Constantly ON, except when a loss of the received carrier signal is detected. Signal Timing 6 13 S(A) S(B) Fm ETU02-MUX A transmit data rate clock for use by an external data source. External Transmit clock 7 14 B(A) B(B) To ETU02-MUX A serial data rate clock input from the data source Table C-1 X.21 data channel connector pin allocation 101

102 Appendix C. Interface Modules C-2. V.35 Data Channel Module Utilizes standard pin-out. The three test pins have been chosen for loops and test. For applications requiring a DTE V.35 interface, clock mode is selected DTE2. Connect the ERC input clock to pins Z(A) and BB(B). V.35 Interface, pin assignment SIGNAL PIN CIRCUIT DIRECTION DESCRIPTION FUNCTION Protective Ground A Frame Chassis ground. May be isolated from signal ground. Signal Ground B Signal Ground Common signal ground. TD P TD(A) To ETU02-MUX Serial digital data from DTE. S TD(B) RD R T RD(A) RD(B) Fm ETU02-MUX Serial digital data at the output of the ETU02-MUX receiver. RTS C RTS To ETU02-MUX An ON signal to the ETU02-MUX when data transmission is desired. CTS D CTS Fm ETU02-MUX Constantly ON. DSR E DSR Fm ETU02-MUX Constantly ON, except during test loops. DTR H DTR To ETU02-MUX Not used. DCD F DCD Fm ETU02-MUX Constantly ON, except when a loss of the received carrier signal is detected. ETC U W ETC(A) ETC(B) To ETU02-MUX A transmitted data rate clock input from the data source. Transmit Y TC(A) Fm ETU02-MUX A transmitted data rate clock for use by an Clock AA TC(B) external data source. Receive Clock V X RC(A) RC(B) Fm ETU02-MUX A received data rate clock for use by an external data source. External Z ERC(A) To ETU02-MUX A received serial data rate clock input from Receive clock BB ERC(B) the DTE. Remote Loop back HH RL To ETU02-MUX When on, commands ETU02-MUX into remote loop back, can disable by DIPSW. Local Loop back JJ LL To ETU02-MUX When on, commands ETU02-MUX into local loop back. Test Indicator KK TM Fm ETU02-MUX ON during any test mode Table C-2 V.35 data channel connector pin allocation 102

103 Appendix C. Interface Modules C-3. RS-530 Data Channel Module Utilizes standard pin-out on a DB25-pin connector. The three test pins have been chosen for loops and test. For applications requiring a DTE RS-530 interface, clock mode DTE2 is selected. Connect the ERC input clock to pins 20(A) and 23(B). RS-530 Interface, pin definition SIGNAL PIN CIRCUIT DIRECTION DESCRIPTION Function Protective Ground 1 Frame Chassis ground. May be isolated from signal ground. Signal 7 AB Common signal ground. Ground Transmitted 2 BA(A) To ETU02-MUX Serial digital data from DTE. Data 14 BA(B) Received Data 3 16 BB(A) BB(B) Fm ETU02-MUX Serial digital data at the output of the ETU02-MUX receiver. Request to Sent 4 19 CA(A) CA(B) To ETU02-MUX A ON signal to the ETU02-MUX when data transmission is desired. Clear to 5 CB(A) Fm ETU02-MUX Constantly ON. Sent 13 CB(B) Data Set Ready 6 22 CC(A) CC(B) Fm ETU02-MUX Constantly ON, Except during test loops. Data Terminal CD(A) CD(B) To ETU02-MUX DTR not used, used for a received serial data rate clock input from the DTE. Ready Data Carrier 8 CF(A) Fm ETU02-MUX Constantly ON, except when a loss of the Detect External Transmit clock Transmit Clock Receive Clock Remote Loop back Local Loop back Test Indicator CF(B) DA(A) DA(B) To ETU02-MUX received carrier signal is detected. A transmitted data rate clock input from the data source DB(A) DB(B) Fm ETU02-MUX A transmitted data rate clock for use by an external data source. 17 DD(A) Fm ETU02-MUX A received data rate clock for use by an 9 DD(B) external data source. 21 RL To ETU02-MUX When on, commands ETU02-MUX into remote loop back. 18 LL To ETU02-MUX When on, commands ETU02-MUX into local loop back. 25 TM Fm ETU02-MUX ON during any test mode Table C-3 RS-530 data channel connector pin allocation 103

104 Appendix C. Interface Modules C-4. RS-232 Data Channel Module Utilizes standard pin-out on a DB25-pin connector. The three test pins have been chosen for loops and test. For applications requiring a DTE RS-232 interface, clock mode is selected DTE2. Connect the ERC input clock to pins 20. The RS-232 maximum clock rate is 128Kbps. For asynchronous use, divide the synchronous rate by 3.3 (64K /3.3 = 19.2K Async). Do not exceed two timeslots assigned (128Kbps) for RS-232. RS-232 Interface, pin assignment SIGNAL Function PIN CIRCUIT DIRECTION DESCRIPTION Protective Ground 1 AA Chassis ground. May be isolated from signal ground. Signal Ground 7 AB Common signal ground. Transmitted 2 BA To ETU02-MUX Serial digital data from DTE. Data Received Data 3 BB Fm ETU02-MUX Serial digital data at the output of the ETU02- MUX receiver. Request to Sent 4 CA To ETU02-MUX A ON signal to the ETU02-MUX when data transmission is desired. Clear to 5 CB Fm ETU02-MUX Constantly ON. Sent Data Set Ready 6 CC Fm ETU02-MUX Constantly ON, Except during test loops. Data Terminal Ready 20 CD To ETU02-MUX DTR not used, used for a received serial data rate clock input from the DTE. Data Carrier 8 CF Fm ETU02-MUX Constantly ON, except when a loss of the Detect External Transmit clock Transmit Clock Receive Clock Remote Loop back Local Loop back Test Indicator received carrier signal is detected. 24 DA To ETU02-MUX A transmitted data rate clock input from the data source. 15 DB Fm ETU02-MUX A transmitted data rate clock for use by an external data source. 17 DD Fm ETU02-MUX A received data rate clock for use by an external data source. 21 RL To ETU02-MUX When on, commands ETU02-MUX into remote loop back. 18 LL To ETU02-MUX When on, commands ETU02-MUX into local loop back. 25 TM Fm ETU02-MUX ON during any test mode Table C-4 RS-232 data channel connector pin allocation 104

105 Appendix C. Interface Modules C-5. RS-530 to RS-449 Adapter Cable When the ETU02-MUX is ordered with an RS-449 interface, the physical interface is a 37-pin male D-type connector wired in accordance with Table C-5. RS-530 to RS-449 adapter cable SIGNAL RS-530 RS-449 RS-449 DESCRIPTION FUNCTION PIN PIN CIRCUIT Protective Ground 1 1 Frame Chassis ground. May be isolated from signal ground. Signal 7 19,20, SG,RC, Common signal ground. Ground 37 SC Transmitted 2 4 SD(A) Serial digital data from DTE. Data SD(B) Received Data RD(A) RD(B) Serial digital data at the output of the ETU02- MUX receiver. Request to Sent RS(A) RS(B) A ON signal to the ETU02-MUX when data transmission is desired. Clear to 5 9 CS(A) Constantly ON. Sent CS(B) Data Set Ready DM(A) DM(B) Constantly ON, Except during test loops. Data Terminal TR(A) TR(B) DTR not used, used for a received serial data rate clock input from the DTE. Ready Data Carrier 8 13 RR(A) Constantly ON, except when a loss of the received Detect External Transmit clock RR(B) TT(A) TT(B) carrier signal is detected. A transmitted data rate clock input from the data source. Transmit Clock ST(A) ST(B) A transmitted data rate clock for use by an external data source. Receive Clock RT(A) RT(B) A received data rate clock for use by an external data source. Remote Loop back RL When on, commands ETU02-MUX into remote loop back. Local Loop back LL When on, commands ETU02-MUX into local loop back. Test Indicator TM ON during any test mode Table C-5 RS-530 to RS-449 pin allocation 105

106 Appendix C. Interface Modules C-6. G K Co-directional Interface Module Utilizing a standard DB15F connector, this module provides an ITU-T G K Co-directional interface for transmission on 4 wires (two twisted pairs). G.703/64Kbps Interface, pin assignment SIGNAL PIN DIRECTION DESCRIPTION Function Protective Ground 4 10 Chassis ground. May be isolated from signal ground. Signal Ground 8 Common signal ground. Transmitted 3 To ETU02-MUX Serial co-directional data from DTE. Data 11 Received Data 1 9 Fm ETU02-MUX Serial co-directional data at the output of the ETU02-MUX receiver. Request to Sent 4 To ETU02-MUX A ON signal to the ETU02-MUX when data transmission is desired. Table C-6 G K Co-directional interface, pin allocation G.703/64Kbps Co-directional Interface Specifications Compliance with ITU-T G.703 Line code 64Kbps Co-directional line code Line 4 wires, one symmetric pair for each direction Interface Connectors 15 pin D-type female Range Up to 800 meters (0.5 miles) Impedance 120 ohms Peak voltage of a mark (pulse) Nominal 1.0V±10% Peak voltage of a space (no pulse) 0V ±0.10V Single pulse width Nominal 3.9us Double pulse width Nominal 7.8us Clock frequency 64 KHz Frequency tracking ±100ppm Frame format Unframed only 106

107 Appendix C. Interface Modules C-7. NRZ/BNC 64K ~ 2048Kbps NRZ Interface Module Utilizing four standard BNC connectors, this module provides an NRZ interface for transmission on 4 coaxial cables. Please refer to the table below for details of the pin out information. NRZ/BNC interface SIGNAL DIRECTION FUNCTION Received Fm ETU02-MUX Data Received Fm ETU02-MUX Timing Transmitted To ETU02-MUX Data Transmit To ETU02-MUX Timing DESCRIPTION Serial NRZ data at the output of the ETU02-MUX receiver. Serial NRZ timing at the output of the ETU02-MUX receiver. Serial NRZ data from DTE. Serial NRZ timing from DTE. Table C-7. G.703 NRZ/BNC pin allocation Specifications: Line Code: NRZ Impedance: 50 ohms Signal Level: Logic "1": 0V +/- 0.3V Logic "0": -1.5V +/- 0.3V Speed: 2048K Max. Settings: (by adjustment of jumpers on interface card) Rx timing; "Normal" or "Inverted" Tx timing; "Normal" or "Inverted" 107

108 Appendix C. Interface Modules C-8. ET10/100 Ethernet Bridge Module Utilizes standard pin out on one RJ-45 connector, providing connection to Ethernet (10Base-T) or Fast Ethernet (100Base- TX) networks utilizing UTP (unshielded twisted pair) cabling. Please refer to the Appendix B for details of the pin out information. MDI MDI-X 1. Tx + 1. Rx + 2. Tx - 2. Rx - 3. Rx + 3. Tx + 6. Rx - 6. Tx - Table C-8a ET10/100 pin allocation DIP Switch Settings DIP State Function 1 ON* Enable MAC filtering OFF Disable Filtering (repeater) 2 ON Enable 802.3x flow control OFF* Disable 802.3x flow control 3 ON NO Auto-negotiation OFF* Auto-negotiation 4 ON Half Duplex 1 OFF* Full Duplex 1 5 ON 10BASE-T LAN speed 1 OFF* 100BASE-TX LAN speed 1 6 ON Enable Auto MDIX OFF* MDI (1:1 to HUB) 7 8 OFF OFF Memory configuration #1 ON OFF Memory configuration #2 OFF ON Memory configuration #3 ON ON Reserved Table C-8b DIP switch settings * factory default settings 1 no effect when sw3 is off (auto-negotiation is on) LED Indicators Designation Indication Full (yellow) ON=Full Duplex Link (green) ON=LAN Link Error (red) ON=LAN Error 100M (yellow) ON=Fast Ethernet Receive (yellow) ON=LAN Rx data Transmit(yellow) ON=LAN Tx data Table C-8c LED indicators Memory configuration detail #1 LAN to WAN 308 packets, WAN to LAN 32 packets #2 LAN to WAN 170 packets, WAN to LAN 170 packets #3 LAN to WAN 32 packets, WAN to LAN 308 packets 108

109 Appendix C. Interface Modules C-9. ET100R Ethernet Router Module When the ETU02-MUX is ordered with an ET100R Interface, the unit is not only an access unit for E1, but also becomes a high performance router for 10Base-T or 100Base-TX Ethernet LAN connection. The ET100R utilizes standard pin out on one RJ-45 connector, providing connection to Ethernet (10Base-T) or Fast Ethernet (100Base-TX) networks over UTP (unshielded twisted pair) cabling. Configuration of the router is beyond the scope of this manual. Please refer to the CDROM based instructions that are included with the router module. The ET100R router module is configured with the CLI Telnet or Web based GUI. The user manual and quick start guide are included on the CDROM. Alternately the router may be configured via the RS-232 console port. A special cable must be used to connect to the modules DIN connector. Pinouts are provided below for reference. MDI 1. Tx + 2. Tx - 3. Rx + 6. Rx - Specifications CPU Hi-Perf. 32 bit ARM 9 RISC CPU Network Protocols TCP/IP, DHCP, ARP, PPP, HDLC, Cisco HDLC, NAT (SNAT, DNAT) Routing Protocols Static, RIP I, RIP II DTE Baud rate Synchronous 2M bps WAN Support T1/E1 LAN Support 10Base-T / 100Base-TX, Auto MDIX Memory 32M bytes SDRAM 8M bytes Flash Memory RS-232 DCE PIN Circuit Direction Description 1 NC 2 RD OUT Receive data 3 TD IN Transmit data 4 DTR IN Data Terminal Ready 5 GND Signal ground 6 DSR OUT Data Set Ready 7 RTS IN Request to Send 8 CTS OUT Clear to Send 9 NC Table C-9 Console port, RS-232, pin allocation 109

110 Appendix C. Interface Modules Figure C10:Single pulse & double pulse sample figure V 1,0 0,5 3,12 μs (3,9 0,78) 3,51 s (3,9 0,39) 3,9 μs 0 4,29 μs (3,9 + 0,39) 6,5 μs (3,9 + 2,6) 7,8 μs (3,9 + 3,9) a) Mask for single pulse V 1,0 0,5 7,02 μs (7,8 0,78) 7,41 μs (7,8 0,39) 7,8 s 0 8,19 μs (7,8 + 0,39) 10,4 μs (7,8 + 2,6) 11,7 s (7,8 + 3,9) b) Mask for double pulse T Note The limits apply to pulses of either polarity. FIGURE 5/G.703 Pulse masks of the 64 kbit/s codirectional interface 110

111 Appendix D. Menu System Appendix D. Menu System Menu System Quick Outline ROOT MENU LEAF MENU AVAILABLE SETTINGS SYSTEM MAIN LINK SUB LINK TIMESLOT MAPPING DATA PORT CONTROL PORT LOOP BACK BERT TEST DATE & TIME MISCELLANEOUS ALARM BUFFER PERFORMANCE MASTER TIMING MAIN LINK SUB LINK INT OSC* CH 1 LINK CH 2 LINK CH 3 LINK CH 4 LINK BACKUP TIMING MAIN LINK SUB LINK INT OSC* FRAME CCS* CAS UNFRAME CRC-4 OFF* ON IDLE CODE 00~FF 7E* RAI (Remote Alarm Indicator) DISABLE* ENABLE LINE CODE HDB3* AMI IMPEDANCE RO(DIP settings) RMT LOOP OFF* ON FRAME CCS* CAS CRC-4 OFF* ON IDLE CODE 00~FF 7E* RAI (Remote Alarm Indicator) DISABLE* ENABLE LINE CODE HDB3* AMI IMPEDANCE RO(DIP settings) 75 OR 120 RMT LOOP OFF* ON FRAMING F SIGNALING S NOT ASSIGNED N DATA 1~4 1~4 DATA ON E1 D VOICE ON E1 V MULTIPLIER N64* N56 CLOCK MODE DCE* DTE1 DTE2 DTE3 CTS ON* RTS TC OUT NORMAL* INVERTED RC OUT NORMAL* INVERTED SPEED * MAIN LINK OFF* LOCAL ANALOG LOCAL DIGITAL LOCAL PAYLOAD REMOTE ANALOG SUB LINK CHANNEL 1 (~4) REMOTE PAYLOAD OFF* LOCAL ANALOG LOCAL DIGITAL REMOTE LOOP OFF* LOCAL ANALOG LOCAL DIGITAL V.54 LOOP FUNCTION OFF* ON CHANNEL 1* SL-ML SL-SL PATTERN 511* E15-1 2E20-1 QRSS 2E23-1 ALL 1 ALL 0 ALT 0011 INSERT ERROR 3IN24 1IN8 NONE* 10E-1 10E-2 10E-3 10E-4 10E-5 10E-6 1IN16 1IN4 SINGLE 10E-7 RESULT (DISPLAY BERT RESULTS) DISPLAY / DEFINE LCD AUTO* ON OFF RESET TO DEFAULT (RESET TO FACTORY DEFAULTS) DISPLAY (LIST ALARMS IN BUFFER) CLEAR (CLEAR ALARMS FROM BUFFER) DISPLAY MAIN LINK SUB LINK CLEAR (CLEAR PERFORMANCE BUFFER) * indicates factory default settings 111

112 Notes: 112

113 ETU02-MUX TECHNICAL INQUIRY FORM CTC Union Technologies Inc. Fax:(886) Attn : Technical Support Division From Company: Name: Tel: ( ) Fax:( ) SYS CONFIGURATION: MODEL: ETU02-MUX/AC ETU02-MUX/DC ETU02-MUX/DP ACTIVITY: As attached in Parameter setting table Tel:(886) support@ctcu.com Taipei, Taiwan Question: ETU02-MUX TECHNICAL INQUIRY FORM

114 CHANNEL I/F MODULE INFORMATION; CHECK INSTALLED MODULES PORT V X G64 NRZ ET10 ET10R ET100 PORT V X G64 NRZ ET10 ET10R ET100 PORT V X G64 NRZ ET10 ET10R ET100 PORT V X G64 NRZ ET10 ET10R ET100 PARAMETERS USER SETTINGS; CHECK ALL THAT ARE APPLICABLE MASTER TIMING MAIN SUB INT.OSC CH1 CH2 CH3 CH4 BACKUP TIMING MAIN SUB INT.OSC MAIN FRAME CCS(PCM31) CAS(PCM30) UNFRAME MAIN CRC4 OFF ON MAIN IDLE CODE 7E Other MAIN RAI DISABLE ENABLE MAIN LINE CODE HDB3 AMI MAIN IMPEDANCE 75Ω(BNC) 120Ω(TP) MAIN RMT LOOP OFF ON SUB FRAME CCS(PCM31) CAS(PCM30) SUB CRC4 OFF ON SUB IDLE CODE 7E Other SUB RAI DISABLE ENABLE SUB LINE CODE HDB3 AMI SUB IMPEDANCE TIMESLOT MAP F=FRAMING; S=SIGNALING; N=NOT ASSIGNED ~4=PORT F D=DATA ON E1 V=VOICE ON E DATA PORTS: PORT 1 PORT 2 PORT 3 PORT 4 PORT MULTIPLIER N64 N64 N64 N64 N56 N56 N56 N56 CLOCK MODE DCE DCE DCE DCE DTE1 DTE1 DTE1 DTE1 DTE2 DTE2 DTE2 DTE2 DTE3 DTE3 DTE3 DTE3 CTS ON ON ON ON RTS RTS RTS RTS TC OUT NORMAL NORMAL NORMAL NORMAL INVERT INVERT INVERT INVERT RC OUT NORMAL NORMAL NORMAL NORMAL INVERT INVERT INVERT INVERT CONTROL PORT ETU02-MUX TECHNICAL INQUIRY FORM

115

116 Transmission Series CTC Union Technologies Co., Ltd. Vienna Technologies Center (Neihu Technology Park) 8F, 60 Zhouzi St., Neihu, Taipei, Taiwan 114 Phone:(886) Fax:(886)